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+1
+Armouring of a frictional interface by mechanical noise
+Elisa El Sergany, Matthieu Wyart, Tom W.J. de Geus
+Physics Institute, ´Ecole Polytechnique F´ed´erale de Lausanne (EPFL) Switzerland
+Abstract
+A dry frictional interface loaded in shear often displays stick-slip. The amplitude of this cycle depends
+on the probability that a slip event nucleates into a rupture, and on the rate at which slip events are
+triggered. This rate is determined by the distribution P(x) of soft spots which yields if the shear stress is
+increased by some amount x. In minimal models of a frictional interface that include disorder, inertia and
+long-range elasticity, we discovered an ‘armouring’ mechanism, by which the interface is greatly stabilised
+after a large slip event: P(x) then vanishes at small arguments, as P(x) ∼ xθ [1]. The exponent θ > 0,
+which exists only in the presence of inertia (otherwise θ = 0), was found to depend on the statistics of
+the disorder in the model, a phenomenon that was not explained. Here, we show that a single-particle
+toy model with inertia and disorder captures the existence of a non-trivial exponent θ > 0, which we can
+analytically relate to the statistics of the disorder.
+1
+Introduction
+We study systems in which disorder and elasticity
+compete, leading to intermittent, avalanche-type re-
+sponse under loading.
+Examples include an elastic
+line being pulled over a disordered pinning potential,
+or frictional interfaces
+[2–4].
+When subject to an
+external load f, such systems are pinned by disor-
+der when the load is below a critical value fc.
+At
+f > fc, the system moves forward at a finite rate. At
+f = fc the system displays a crackling-type response
+described by avalanches whose sizes and durations are
+distributed according to powerlaws.
+A key aspect of such systems is the distribution
+of soft spots [5]. If we define x as the force increase
+needed to trigger an instability locally, then increas-
+ing the remotely applied force by ∆f will trigger
+na ∝
+� ∆f
+0
+P(x)dx avalanches, with P(x) the probabil-
+ity density of x. The relevant behaviour of P(x) there-
+fore is that at small x. Let us assume that P(x) ∼ xθ
+at small x, such that na ∝ (∆f)θ+1.
+Classical models used to study the depinning tran-
+sition consider an over-damped dynamics [2]. In that
+case, it can be shown that θ = 0 [2]. This result is
+not true for certain phenomena, including the plastic-
+ity of amorphous solids or mean-field spin glasses. In
+these cases, due to the fact that elastic interactions
+are long-range and can vary in sign (which is not the
+case for the depinning transition, where a region that
+is plastically rearranged can only destabilise other re-
+gions), one can prove that θ > 0, as reviewed in [5, 6].
+Recently, we studied simple models of dry fric-
+tional interface [1, 7]. We considered disorder, long-
+range elastic interactions along the interface. These
+interactions are strictly positive as in the usual class
+of the depinning transition. However, we studied the
+role of inertia, that turns out to have dramatic ef-
+fects.
+Inertia causes transient overshoots and un-
+dershoots of the stress resulting from a local plas-
+tic event. It thus generates a mechanical noise, that
+lasts until damping ultimately takes place. Remark-
+ably, we found that right after system-spanning slip
+events, θ > 0 [1] in the presence of inertia.
+Intu-
+itively, such an ‘armouring’ mechanism results from
+the mechanical noise stemming inertial effects, that
+destabilises spots close to an instability (i.e. small
+x), thus depleting P(x) at small argument.
+This
+property is consequential: the number of avalanches
+of plastic events triggered after a system-spanning
+rupture is very small. As a consequence, the inter-
+face can increase its load when driven quasistatically
+in a finite system, without much danger of trigger-
+ing large slip events. The interface therefore present
+larger stick-slip cycles due to this effect, as sketched in
+Fig. 1. Thus, one of the central quantities governing
+the stick-slip amplitude is θ [1].
+Our previous model [1] divided the interface in
+blocks whose mechanical response was given by a po-
+tential energy landscape that, as a function of slip,
+comprised a sequence of parabolic wells with equal
+curvature. We drew the widths w of each well ran-
+domly from a Weibull distribution, such that its dis-
+arXiv:2301.13802v1  [cond-mat.soft]  31 Jan 2023
+
+2
+tribution Pw(w) ∼ wk at small k.
+We empirically
+found θ ≃ 2.5 for k = 1 and θ ≃ 1.4 for k = 0.2.
+Here we present a toy model for a region of space
+that stops moving at the end of a large slip event. In
+the most idealised view, we describe this region as a
+single particle that moves over a disordered potential
+energy landscape, and that slows down due to dissipa-
+tion. We model this potential energy landscape by a
+sequence of parabolic potentials that have equal cur-
+vature κ but different widths taken from Pw(w), with
+w the width of a parabola. In this model, x = κw/2
+and is thus proportional to the width of the well in
+which the particle stops.
+Below we prove that for
+such a model, P(x) ∼ xk+2 if Pw(w) ∼ wk.
+This
+result explains both why θ > 0 and why this expo-
+nent in non-universal, as it depends on k that char-
+acterises the disorder. Although this prediction does
+not match quantitatively our previous observations,
+the agreement is already noticeable for such a sim-
+ple model. We support our argument with analytical
+proofs, and verify our conclusion numerically.
+The
+generality of our argument suggests that the presence
+of a non-trivial exponent θ may hold in other depin-
+ning systems, as long a inertia is present.
+force
+slip
+(a)
+(b)
+avalanche
+slip
+Figure 1. (a) Sketch of stick-slip response: “slip” events
+punctuate periods in which the interface is macroscopi-
+cally stuck, but microscopic events (“avalanches”) do oc-
+cur. The number of avalanches na ∝ (∆f)θ+1, which can
+be linked to (b) the distribution of soft spots. x is thereby
+the amount of force needed to trigger an instability locally.
+Right after a large slip event, its distribution empirically
+scales like P(x) ∼ xθ at small x as indicated (log-scale
+implied).
+2
+Model
+During a big slip event, all regions in space are moving
+but eventually slow down and stop. We model this by
+considering a single region in space in which a particle
+of finite mass is thrown into the potential energy land-
+scape at a finite velocity. In the simplest case, this
+particle is “free”, such that it experiences no external
+driving and stops due to dissipation, see Fig. 2. This
+corresponds to the Prandtl-Tomlinson [8–10] model
+that describes the dynamics of one (driven) particle
+in a potential energy landscape. The equation of mo-
+tion of the “free” particle reads
+m¨r = fe(r) − η ˙r.
+(1)
+with r the particle’s position, m its mass, and η
+a damping coefficient.
+fe(r) is the restoring force
+due to the potential energy landscape.
+We con-
+sider a potential energy landscape that consists of a
+sequence of finite-sized, symmetric, quadratic wells,
+such that the potential energy inside a well i is given
+by U(r) = (κ/2)(r − ri
+min)2 + U i
+0 for ri
+y < r ≤ ri+1
+y
+,
+with wi ≡ ri+1
+y
+− ri
+y the width of the well, κ the
+elastic constant, ri
+min ≡ (ri
+y + ri+1
+y
+)/2 the position of
+the center of the well, and U i
+0 = κ(wi)2/8 an unim-
+portant offset.
+The elastic force deriving from this
+potential energy is fe(r) ≡ −∂xU(r) = κ(ri
+min − r).
+With κ is constant, the landscape is parameterised by
+the distance between two subsequent cusps wi, which
+we assume identically distributed (iid) according to
+a distribution Pw(w). We consider underdamped dy-
+namics corresponding to η2 < 4mκ. Within a well,
+the dynamics is simply that of a underdamped oscil-
+lator, as recalled in Appendix A.
+0.0
+0.5
+1.0
+1.5
+2.0
+λt
+0
+1
+2
+3
+E/⟨U⟩
+0
+4
+8
+r/⟨w⟩
+−1
+0
+U/⟨U⟩
+Figure 2. Evolution of the kinetic energy E as a function
+of position r (in red) of the “free” particle ‘thrown’ into
+a potential energy landscape (shown in the inset). Every
+entry into a new well is indicated using a marker. A thin
+green line shows the evolution of the total energy (with
+the definition of the inset, it has the local minimum of the
+last well as arbitrary offset).
+
+3
+3
+Stopping well
+Distribution.
+We are interested in the width of the
+well in which the particle eventually stops. Suppose
+that a particle enters a well of width w with a kinetic
+energy E. The particle stops in that well if E < Ec(w),
+with Ec the minimum kinetic energy with which the
+particle needs to enter a well of width w to be able to
+exit. The distribution of wells in which particles stop
+in that case is
+Ps(w) ∼ Pw(w)P(E < Ec(w)),
+(2)
+with Pw(w) the probability density of well widths,
+and Ps(w) the probability of well widths in which the
+particle stops. Within one well, the particle is sim-
+ply a damped harmonic oscillator as has been studied
+abundantly. In the limit of a weakly damped system,
+the amount of kinetic energy lost during one cycle is
+∆E = κw2(1 − exp(−2π/Q))/8 with the quality fac-
+tor Q =
+�
+4mκ/η2 − 1. The minimal kinetic energy
+with which the particle needs to enter the well in or-
+der to be able to exist is thus Ec = ∆E ∝ w2 (see
+Appendix B for the exact calculation of Ec). Further-
+more, if P(E) is a constant at small argument (as we
+will argue below), then
+P(E < Ec(w)) =
+� Ec
+0
+P(E)dE ∼ Ec(w).
+(3)
+Therefore, the particle stops in a well whose width is
+distributed as
+Ps(w) ∼ w2Pw(w).
+(4)
+Central result.
+Once stopped, the force, x, by
+which we need to tilt the well in which the particle
+stopped, in order for it to exit again is x = κw/2 1,
+such that our central result is that
+P(x) ∼ x2Pw(x).
+(5)
+For example, if Pw(w) ∼ wk at small w, we predict
+that
+P(x) ∼ x2+k.
+(6)
+Energy at entry.
+We will now argue that the den-
+sity of kinetic energy with which the particle enters
+the final well, P(E), is finite at small E.
+For one
+realisation, E results from passing many wells with
+random widths. If its kinetic energy is much larger
+than the potential energy of the typical wells, it will
+1Without external forces, the particle ends in the local min-
+imum – the center of the well.
+not stop. We thus consider that the particle energy
+has decreased up to some typical kinetic energy E0 of
+the order of the typical potential energy κ⟨w2⟩/8. If
+the particle exits the next well, at exit it will have a
+kinetic energy K = E0 − ∆E(E0, w). For a given E0
+and distributed w, we have:
+P(E) =
+�
+dw Pw(w) δ(K(E0, w) − E).
+(7)
+It thus implies that:
+P(E = 0) = Pw(w∗)/
+��∂wK
+��
+w=w∗
+(8)
+w∗ is the well width for which the particle reaches the
+end of the well with zero velocity, i.e. E0 = Ec(w∗).
+By assumption, Pw(w∗) > 0. Furthermore we prove
+in Appendix C that ∂wK|w=w∗ = κw∗/2 > 0. Over-
+all, it implies that P(E = 0) > 0, i.e. P(E) does not
+vanish as E → 0, from which our conclusions follow.
+Here we give a simple argument for ∂wK|w=w∗ =
+κw∗/2 > 0. Given E0, but an infinitesimally smaller
+well of width w∗ −δw, the particle will enter the next
+well. Because the velocity is negligible in the vicinity
+of w∗, the damping is negligible. Therefore, δK is of
+the order of the difference in potential energy on a
+scale δw, δU = U(w∗) − U(w∗ − δw) ≈ κw∗δw/2, as
+we illustrate in Fig. 3. We thus find that ∂wK|w=w∗ =
+limδw→0 δK/δw = κw∗/2.
+−w∗/2
+0
+w∗/2
+position
+0
+energy
+1
+2κw∗δw
+δw
+1
+2κw∗δw
+δw
+potential energy U
+kinetic energy E
+total energy E + U
+Figure 3. Evolution of the kinetic energy E (red), po-
+tential energy U (black), and total energy E + V (green)
+for a particle that has entered a well of width w∗ with a
+kinetic energy E0 = Ec(w∗) such that it stops just. Con-
+sequently, ∂r(E + V )|w∗/2 = 0, which can be decomposed
+in ∂rV |w∗/2 = κw∗/2 such that ∂rE|w∗/2 = −κw∗/2, as
+indicated using thin lines.
+
+4
+4
+Numerical support
+Objective.
+We now numerically verify our predic-
+tion that P(x) ∼ xk+2 (Eq. (6)). We simulate a large
+number of realisations of a potential energy landscape
+constructed from randomly drawn widths (consider-
+ing different distributions Pw(w)) and constant cur-
+vature. We study the distribution of stopping wells
+if a “free” particle is ‘thrown’ into the landscape at
+a high initial velocity (much larger than vc(⟨w⟩) such
+that particle transverses many wells before stopping).
+Map.
+We find an analytical solution for Eq. (1) in
+the form of a map. In particular, we derive the evo-
+lution of the position in a well based on an initial po-
+sition −w/2 and velocity in Appendix A. This maps
+the velocity with which the particle enters a well at
+position w/2, to an exit velocity which corresponds
+to the entry velocity of the next well, etc.
+Stopping well.
+We record the width of the stop-
+ping well, x, and the velocity V with which the parti-
+cle enters the final well. We find clear evidence for the
+scaling P(x) ∼ xk+2 in Fig. 4. Perturbing the evolu-
+tion with random force kicks2 changes nothing to our
+observations, as included in Fig. 4 (see caption). We,
+furthermore, show that the probability density of the
+kinetic energy with which the particle enters the final
+well, P(E), is constant as small argument in Fig. 5.
+5
+Concluding remarks
+Our central result is that P(x) ∼ x2Pw(x) in our
+toy model. For a disorder Pw(w) ∼ wk we thus find
+P(x) ∼ xk+2. We expect this result to qualitatively
+apply to generic depinning systems in the presence of
+inertia. In particular they are qualitatively (but not
+quantitatively) consistent with our previous empiri-
+cal observations θ ≃ 2.5 for k = 1 [1] and θ ≃ 1.4
+for k = 0.2. A plausible limitation of our approach
+is underlined by the following additional observation:
+in Ref. [1], it was found that for x to be small, the
+stopping well was typically small (by definition), but
+also that the next well had to be small. Such corre-
+lations can exist only if the degree of freedom con-
+sidered had visited the next well, before coming back
+and stopping. This scenario cannot occur in our sim-
+ple description where the particle only moves forward,
+except when it oscillates in its final well.
+2Such the for each well is tilted with a random force that we
+take independent and identically distributed (iid) according to
+a normal distribution with zero mean.
+10−2
+100
+x
+10−5
+100
+P(x)/cx
+1
+2
+1
+3
+1
+4
+k = 0 1 2
+weibull
+power
+uniform
+Figure 4.
+Width of the stopping well, x, for different
+Pw(w): a uniform, Weibull, and powerlaw distribution,
+that scale as Pw(w) ∼ wk at small w, as indicated in the
+legend (the bottom row for each distribution corresponds
+to perturbing the dynamcs with random force kicks, tilt-
+ing individual wells by a force F = N(0, 0.1), with N the
+normal distribution; the top row corresponds to F = 0).
+To emphasise the scaling, the distributions have been
+rescaled by a fit of the prefactors: P(x) = cxxk+2. Fur-
+thermore, we use m = κ = 1, η = 0.1, v0 = N(100, 10),
+and ⟨w⟩ ≈ 1.
+10−5
+10−1
+E
+10−2
+100
+P(E)/ce
+Figure 5.
+The kinetic energy with which the particle
+enters the well in which it stops for different realisations,
+P(E), normalised by its prefactor ce (that is here simply
+the density of the first bin). See Fig. 4 for legend.
+
+5
+References
+[1] T.W.J. de Geus, M. Popovi´c, W. Ji, A. Rosso, and
+M. Wyart. How collective asperity detachments nucleate slip
+at frictional interfaces. Proc. Natl. Acad. Sci., 116(48):
+23977–23983, 2019. doi: 10.1073/pnas.1906551116.
+arXiv: 1904.07635.
+[2] D.S. Fisher. Collective transport in random media: From
+superconductors to earthquakes. Phys. Rep., 301(1–3):
+113–150, 1998. doi: 10.1016/S0370-1573(98)00008-8.
+arXiv: cond-mat/9711179.
+[3] O. Narayan and D.S. Fisher. Threshold critical dynamics of
+driven interfaces in random media. Phys. Rev. B, 48(10):
+7030–7042, 1993. doi: 10.1103/PhysRevB.48.7030.
+[4] M. Kardar. Nonequilibrium dynamics of interfaces and lines.
+Phys. Rep., 301(1–3):85–112, 1998.
+doi: 10.1016/S0370-1573(98)00007-6.
+arXiv: cond-mat/9704172.
+[5] M. M¨uller and M. Wyart. Marginal Stability in Structural,
+Spin, and Electron Glasses. Annu. Rev. Condens. Matter
+Phys., 6(1):177–200, 2015.
+doi: 10.1146/annurev-conmatphys-031214-014614.
+[6] Alberto Rosso, James P Sethna, and Matthieu Wyart.
+Avalanches and deformation in glasses and disordered
+systems. arXiv preprint: 2208.04090, 2022.
+doi: 10.48550/arXiv.2208.04090.
+[7] T.W.J. de Geus and M. Wyart. Scaling theory for the
+statistics of slip at frictional interfaces. Phys. Rev. E, 106
+(6):065001, 2022. doi: 10.1103/PhysRevE.106.065001.
+arXiv: 2204.02795.
+[8] L. Prandtl. Ein Gedankenmodell zur kinetischen Theorie der
+festen K¨orper. Z. angew. Math. Mech., 8(2):85–106, 1928.
+doi: 10.1002/zamm.19280080202.
+[9] G.A. Tomlinson. CVI. A molecular theory of friction. The
+London, Edinburgh, and Dublin Philosophical Magazine
+and Journal of Science, 7(46):905–939, 1929.
+doi: 10.1080/14786440608564819.
+[10] V.L. Popov and J.A.T. Gray. Prandtl-Tomlinson Model: A
+Simple Model Which Made History. In E. Stein, editor, The
+History of Theoretical, Material and Computational
+Mechanics - Mathematics Meets Mechanics and
+Engineering, volume 1, pages 153–168. Springer Berlin
+Heidelberg, 2014. ISBN 978-3-642-39904-6
+978-3-642-39905-3. doi: 10.1007/978-3-642-39905-3 10.
+A
+Analytical solution
+Anasatz.
+We look for the solution of a general lin-
+ear equation of motion in one well
+m¨r + η ˙r + κr − F = 0.
+(9)
+where the position r is expressed relative to the local
+minimum in potential energy. The external force F
+tilts the potential energy landscape and will be used
+as a perturbation to check the robustness of our ar-
+gument. An ansatz to this differential equation is
+r(τ) = αe−λ−τ + βe−λ+τ + ∆r,
+(10)
+where ∆r = F/κ, and τ is the time that the parti-
+cle has spent since the entry in the current well at
+r(τ = 0) ≡ −w/2. We denote the particle’s veloc-
+ity v(τ) ≡ ˙r(τ), whereby we take v(τ = 0) ≡ v0.
+Substituting this ansatz in Eq. (9) leads to λ± =
+(η ±
+�
+η2 − 4mκ)/(2m). The prefactors α and β are
+set by the initial conditions such that
+α, β = ±r0λ± + v0
+λ+ − λ−
+,
+(11)
+with r0 ≡ −w/2 − ∆r.
+Underdamped.
+We recognise that if λ± are real
+(η2 > 4mκ), the dynamics are overdamped and the
+velocity decays exponentially.
+Conversely, the un-
+derdamped dynamics that we consider correspond to
+η2 < 4mκ 3.
+Oscillator.
+In the underdamped case, λ± and α, β
+are complex conjugates. This allows us to simplify
+the solution by expressing those coefficients as λ± =
+λ ± iω and α, β = (L/2)e±iφ as follows 4
+r(τ) = Le−λτ cos(ωτ + φ) + ∆r.
+(12)
+We remark that the velocity v(τ) can be expressed as
+a phase shift with respect to r(τ) 5
+v(τ) = −Ae−λτ cos
+�
+ωτ + φ − arctan
+�ω
+λ
+��
+(13)
+with A = λL
+�
+1 + (ω/λ)2. We summarise the ampli-
+tudes, frequency, and phase. From λ± we find
+λ =
+η
+2m,
+ω2 = κ
+m −
+� η
+2m
+�2
+.
+(14)
+Furthermore, Eq. (11) gives
+α, β = 1
+2
+�
+r0 ∓ i(λr0 + v0)/ω
+�
+,
+(15)
+such that
+L2 = 4
+�
+Re(α)2 + Im(α)2�
+(16)
+=
+�
+(ωr0)2 + (λr0 + v0)2�
+/ω2,
+(17)
+and
+φ = χπ + arctan (Im(α)/Re(α))
+(18)
+= χπ − arctan (λ/ω + v0/(ωr0)) ,
+(19)
+where χ depends on α 6.
+3Note that our solution warrants some caution for critical
+damping η2 = 4mκ.
+4cos(z) = (eiz + e−iz)/2
+5a cos(z) + b sin(z) = sgn(a)
+√
+a2 + b2 cos (z − arctan(b/a))
+6Re(α) ≥ 0 → χ = 0. (Re(α) < 0, Im(α) ≥ 0) → χ = 1.
+(Re(α) < 0, Im(α) < 0) → χ = −1.
+
+6
+B
+Exiting well
+We will show that the minimum kinetic energy with
+which the particle needs to enter a well to be able
+to exit Ec ∝ w2, whereby we consider F = 0. The
+particle exits the well if v0 > vc. vc thus corresponds
+to the case that r(τe) = w/2 = −r0 for which v(τe) =
+0. Let us make the ansatz that v0 = vc = w/τc and
+look for the solution of τc.
+We note that on the interval τ ∈ [0, τe) the posi-
+tion is strictly monotonically increasing. The solution
+of v(τn) = 0 corresponds to
+ωτn + φ − arctan(ω/λ) = (n + 1/2)π,
+n ∈ Z. (20)
+The for us relevant solution is τe = min(τn > 0) 7 .
+r(τe) = w/2 corresponds to
+Le−λτe = w/(2c0),
+(21)
+with
+c0 = cos((n + 1/2)π + arctan(ω/λ)).
+(22)
+Using the definition of τe in Eq. (20) leads to
+Leλφ/ω = w/(2c0c1),
+(23)
+with
+c1 = e−λ(n+1/2)π/ω−(λ/ω) arctan(ω/λ).
+(24)
+Furthermore,
+L2 = 1
+4
+�
+ω2 + (2/τc − λ)2�
+(w/ω)2,
+(25)
+φ = sign (2/τc − λ) π + arctan
+��
+2/τc − λ
+�
+/ω
+�
+, (26)
+such that
+L′eλφ/ω = 1/(2c0c1),
+(27)
+with L′ = L/w.
+Eq. (27) is w independent and can
+be solved for τc = τc(λ, ω, n), proving that vc = w/τc.
+This results thus corresponds to
+Ec = 1
+2mv2
+c = m
+2τ 2c
+w2.
+(28)
+as we used to go from Eq. (2) to obtain Eq. (4) using
+Eq. (3).
+7i.e. n = ±1 depending on (r0, v0)
+C
+Entry kinetic energy
+With K the kinetic energy at exiting the well, we show
+that ∂wK
+��
+w=w∗ > 0. We again consider F = 0. In
+particular, we show that
+∂wK = m ve ∂wve > 0.
+(29)
+The derivative of the velocity as a function of the well
+size is
+∂rv = ∂τv/∂τr = a(τ)/v(τ),
+(30)
+where the acceleration a(τ) ≡ ¨r(τ) = αλ2
+−e−λ−τ +
+βλ2
++e−λ+τ. By evaluating this expression with initial
+conditions r(τ = 0) = −w∗/2 and v(τ = 0) = 0, we
+find
+∂wK
+��
+w=w∗ = m (αλ2
+− + βλ2
++) = −m
+2 (λ2 + ω2) w∗.
+(31)
+From the definitions of λ and ω in Eq. (14), we thus
+find
+∂wK
+��
+w=w∗ = −κw∗/2,
+(32)
+as we argued above to show that P(E = 0) > 0 using
+Eq. (8).
+
diff --git a/-dFST4oBgHgl3EQfcTgr/content/tmp_files/load_file.txt b/-dFST4oBgHgl3EQfcTgr/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..11fc0266febc8a581d1eaa806a09fbe094a2e04a
--- /dev/null
+++ b/-dFST4oBgHgl3EQfcTgr/content/tmp_files/load_file.txt
@@ -0,0 +1,328 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf,len=327
+page_content='1  Armouring of a frictional interface by mechanical noise  Elisa El Sergany, Matthieu Wyart, Tom W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' de Geus  Physics Institute, ´Ecole Polytechnique F´ed´erale de Lausanne (EPFL) Switzerland  Abstract  A dry frictional interface loaded in shear often displays stick-slip.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The amplitude of this cycle depends  on the probability that a slip event nucleates into a rupture, and on the rate at which slip events are  triggered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' This rate is determined by the distribution P(x) of soft spots which yields if the shear stress is  increased by some amount x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In minimal models of a frictional interface that include disorder, inertia and  long-range elasticity, we discovered an ‘armouring’ mechanism, by which the interface is greatly stabilised  after a large slip event: P(x) then vanishes at small arguments, as P(x) ∼ xθ [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The exponent θ > 0,  which exists only in the presence of inertia (otherwise θ = 0), was found to depend on the statistics of  the disorder in the model, a phenomenon that was not explained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Here, we show that a single-particle  toy model with inertia and disorder captures the existence of a non-trivial exponent θ > 0, which we can  analytically relate to the statistics of the disorder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  1  Introduction  We study systems in which disorder and elasticity  compete, leading to intermittent, avalanche-type re-  sponse under loading.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Examples include an elastic  line being pulled over a disordered pinning potential,  or frictional interfaces  [2–4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  When subject to an  external load f, such systems are pinned by disor-  der when the load is below a critical value fc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  At  f > fc, the system moves forward at a finite rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' At  f = fc the system displays a crackling-type response  described by avalanches whose sizes and durations are  distributed according to powerlaws.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  A key aspect of such systems is the distribution  of soft spots [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' If we define x as the force increase  needed to trigger an instability locally, then increas-  ing the remotely applied force by ∆f will trigger  na ∝  � ∆f  0  P(x)dx avalanches, with P(x) the probabil-  ity density of x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The relevant behaviour of P(x) there-  fore is that at small x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Let us assume that P(x) ∼ xθ  at small x, such that na ∝ (∆f)θ+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Classical models used to study the depinning tran-  sition consider an over-damped dynamics [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In that  case, it can be shown that θ = 0 [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' This result is  not true for certain phenomena, including the plastic-  ity of amorphous solids or mean-field spin glasses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In  these cases, due to the fact that elastic interactions  are long-range and can vary in sign (which is not the  case for the depinning transition, where a region that  is plastically rearranged can only destabilise other re-  gions), one can prove that θ > 0, as reviewed in [5, 6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Recently, we studied simple models of dry fric-  tional interface [1, 7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We considered disorder, long-  range elastic interactions along the interface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' These  interactions are strictly positive as in the usual class  of the depinning transition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' However, we studied the  role of inertia, that turns out to have dramatic ef-  fects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Inertia causes transient overshoots and un-  dershoots of the stress resulting from a local plas-  tic event.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' It thus generates a mechanical noise, that  lasts until damping ultimately takes place.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Remark-  ably, we found that right after system-spanning slip  events, θ > 0 [1] in the presence of inertia.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Intu-  itively, such an ‘armouring’ mechanism results from  the mechanical noise stemming inertial effects, that  destabilises spots close to an instability (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' small  x), thus depleting P(x) at small argument.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  This  property is consequential: the number of avalanches  of plastic events triggered after a system-spanning  rupture is very small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' As a consequence, the inter-  face can increase its load when driven quasistatically  in a finite system, without much danger of trigger-  ing large slip events.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The interface therefore present  larger stick-slip cycles due to this effect, as sketched in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Thus, one of the central quantities governing  the stick-slip amplitude is θ [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Our previous model [1] divided the interface in  blocks whose mechanical response was given by a po-  tential energy landscape that, as a function of slip,  comprised a sequence of parabolic wells with equal  curvature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We drew the widths w of each well ran-  domly from a Weibull distribution, such that its dis-  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='13802v1  [cond-mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='soft]  31 Jan 2023  2  tribution Pw(w) ∼ wk at small k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We empirically  found θ ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='5 for k = 1 and θ ≃ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='4 for k = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Here we present a toy model for a region of space  that stops moving at the end of a large slip event.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In  the most idealised view, we describe this region as a  single particle that moves over a disordered potential  energy landscape, and that slows down due to dissipa-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We model this potential energy landscape by a  sequence of parabolic potentials that have equal cur-  vature κ but different widths taken from Pw(w), with  w the width of a parabola.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In this model, x = κw/2  and is thus proportional to the width of the well in  which the particle stops.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Below we prove that for  such a model, P(x) ∼ xk+2 if Pw(w) ∼ wk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  This  result explains both why θ > 0 and why this expo-  nent in non-universal, as it depends on k that char-  acterises the disorder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Although this prediction does  not match quantitatively our previous observations,  the agreement is already noticeable for such a sim-  ple model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We support our argument with analytical  proofs, and verify our conclusion numerically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  The  generality of our argument suggests that the presence  of a non-trivial exponent θ may hold in other depin-  ning systems, as long a inertia is present.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  force  slip  (a)  (b)  avalanche  slip  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (a) Sketch of stick-slip response: “slip” events  punctuate periods in which the interface is macroscopi-  cally stuck, but microscopic events (“avalanches”) do oc-  cur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The number of avalanches na ∝ (∆f)θ+1, which can  be linked to (b) the distribution of soft spots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' x is thereby  the amount of force needed to trigger an instability locally.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Right after a large slip event, its distribution empirically  scales like P(x) ∼ xθ at small x as indicated (log-scale  implied).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  2  Model  During a big slip event, all regions in space are moving  but eventually slow down and stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We model this by  considering a single region in space in which a particle  of finite mass is thrown into the potential energy land-  scape at a finite velocity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In the simplest case, this  particle is “free”, such that it experiences no external  driving and stops due to dissipation, see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' This  corresponds to the Prandtl-Tomlinson [8–10] model  that describes the dynamics of one (driven) particle  in a potential energy landscape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The equation of mo-  tion of the “free” particle reads  m¨r = fe(r) − η ˙r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (1)  with r the particle’s position, m its mass, and η  a damping coefficient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  fe(r) is the restoring force  due to the potential energy landscape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We con-  sider a potential energy landscape that consists of a  sequence of finite-sized, symmetric, quadratic wells,  such that the potential energy inside a well i is given  by U(r) = (κ/2)(r − ri  min)2 + U i  0 for ri  y < r ≤ ri+1  y  ,  with wi ≡ ri+1  y  − ri  y the width of the well, κ the  elastic constant, ri  min ≡ (ri  y + ri+1  y  )/2 the position of  the center of the well, and U i  0 = κ(wi)2/8 an unim-  portant offset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  The elastic force deriving from this  potential energy is fe(r) ≡ −∂xU(r) = κ(ri  min − r).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  With κ is constant, the landscape is parameterised by  the distance between two subsequent cusps wi, which  we assume identically distributed (iid) according to  a distribution Pw(w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We consider underdamped dy-  namics corresponding to η2 < 4mκ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Within a well,  the dynamics is simply that of a underdamped oscil-  lator, as recalled in Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='0  λt  0  1  2  3  E/⟨U⟩  0  4  8  r/⟨w⟩  −1  0  U/⟨U⟩  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Evolution of the kinetic energy E as a function  of position r (in red) of the “free” particle ‘thrown’ into  a potential energy landscape (shown in the inset).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Every  entry into a new well is indicated using a marker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' A thin  green line shows the evolution of the total energy (with  the definition of the inset, it has the local minimum of the  last well as arbitrary offset).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  3  3  Stopping well  Distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We are interested in the width of the  well in which the particle eventually stops.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Suppose  that a particle enters a well of width w with a kinetic  energy E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The particle stops in that well if E < Ec(w),  with Ec the minimum kinetic energy with which the  particle needs to enter a well of width w to be able to  exit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The distribution of wells in which particles stop  in that case is  Ps(w) ∼ Pw(w)P(E < Ec(w)),  (2)  with Pw(w) the probability density of well widths,  and Ps(w) the probability of well widths in which the  particle stops.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Within one well, the particle is sim-  ply a damped harmonic oscillator as has been studied  abundantly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In the limit of a weakly damped system,  the amount of kinetic energy lost during one cycle is  ∆E = κw2(1 − exp(−2π/Q))/8 with the quality fac-  tor Q =  �  4mκ/η2 − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The minimal kinetic energy  with which the particle needs to enter the well in or-  der to be able to exist is thus Ec = ∆E ∝ w2 (see  Appendix B for the exact calculation of Ec).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Further-  more, if P(E) is a constant at small argument (as we  will argue below), then  P(E < Ec(w)) =  � Ec  0  P(E)dE ∼ Ec(w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (3)  Therefore, the particle stops in a well whose width is  distributed as  Ps(w) ∼ w2Pw(w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (4)  Central result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Once stopped, the force, x, by  which we need to tilt the well in which the particle  stopped, in order for it to exit again is x = κw/2 1,  such that our central result is that  P(x) ∼ x2Pw(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (5)  For example, if Pw(w) ∼ wk at small w, we predict  that  P(x) ∼ x2+k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (6)  Energy at entry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We will now argue that the den-  sity of kinetic energy with which the particle enters  the final well, P(E), is finite at small E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  For one  realisation, E results from passing many wells with  random widths.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' If its kinetic energy is much larger  than the potential energy of the typical wells, it will  1Without external forces, the particle ends in the local min-  imum – the center of the well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  not stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We thus consider that the particle energy  has decreased up to some typical kinetic energy E0 of  the order of the typical potential energy κ⟨w2⟩/8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' If  the particle exits the next well, at exit it will have a  kinetic energy K = E0 − ∆E(E0, w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' For a given E0  and distributed w, we have:  P(E) =  �  dw Pw(w) δ(K(E0, w) − E).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (7)  It thus implies that:  P(E = 0) = Pw(w∗)/  ��∂wK  ��  w=w∗  (8)  w∗ is the well width for which the particle reaches the  end of the well with zero velocity, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' E0 = Ec(w∗).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  By assumption, Pw(w∗) > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Furthermore we prove  in Appendix C that ∂wK|w=w∗ = κw∗/2 > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Over-  all, it implies that P(E = 0) > 0, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' P(E) does not  vanish as E → 0, from which our conclusions follow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Here we give a simple argument for ∂wK|w=w∗ =  κw∗/2 > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Given E0, but an infinitesimally smaller  well of width w∗ −δw, the particle will enter the next  well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Because the velocity is negligible in the vicinity  of w∗, the damping is negligible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Therefore, δK is of  the order of the difference in potential energy on a  scale δw, δU = U(w∗) − U(w∗ − δw) ≈ κw∗δw/2, as  we illustrate in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We thus find that ∂wK|w=w∗ =  limδw→0 δK/δw = κw∗/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  −w∗/2  0  w∗/2  position  0  energy  1  2κw∗δw  δw  1  2κw∗δw  δw  potential energy U  kinetic energy E  total energy E + U  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Evolution of the kinetic energy E (red), po-  tential energy U (black), and total energy E + V (green)  for a particle that has entered a well of width w∗ with a  kinetic energy E0 = Ec(w∗) such that it stops just.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Con-  sequently, ∂r(E + V )|w∗/2 = 0, which can be decomposed  in ∂rV |w∗/2 = κw∗/2 such that ∂rE|w∗/2 = −κw∗/2, as  indicated using thin lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  4  4  Numerical support  Objective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We now numerically verify our predic-  tion that P(x) ∼ xk+2 (Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (6)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We simulate a large  number of realisations of a potential energy landscape  constructed from randomly drawn widths (consider-  ing different distributions Pw(w)) and constant cur-  vature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We study the distribution of stopping wells  if a “free” particle is ‘thrown’ into the landscape at  a high initial velocity (much larger than vc(⟨w⟩) such  that particle transverses many wells before stopping).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We find an analytical solution for Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (1) in  the form of a map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In particular, we derive the evo-  lution of the position in a well based on an initial po-  sition −w/2 and velocity in Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' This maps  the velocity with which the particle enters a well at  position w/2, to an exit velocity which corresponds  to the entry velocity of the next well, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Stopping well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We record the width of the stop-  ping well, x, and the velocity V with which the parti-  cle enters the final well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We find clear evidence for the  scaling P(x) ∼ xk+2 in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Perturbing the evolu-  tion with random force kicks2 changes nothing to our  observations, as included in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 4 (see caption).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We,  furthermore, show that the probability density of the  kinetic energy with which the particle enters the final  well, P(E), is constant as small argument in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  5  Concluding remarks  Our central result is that P(x) ∼ x2Pw(x) in our  toy model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' For a disorder Pw(w) ∼ wk we thus find  P(x) ∼ xk+2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We expect this result to qualitatively  apply to generic depinning systems in the presence of  inertia.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In particular they are qualitatively (but not  quantitatively) consistent with our previous empiri-  cal observations θ ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='5 for k = 1 [1] and θ ≃ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='4  for k = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' A plausible limitation of our approach  is underlined by the following additional observation:  in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' [1], it was found that for x to be small, the  stopping well was typically small (by definition), but  also that the next well had to be small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Such corre-  lations can exist only if the degree of freedom con-  sidered had visited the next well, before coming back  and stopping.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' This scenario cannot occur in our sim-  ple description where the particle only moves forward,  except when it oscillates in its final well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  2Such the for each well is tilted with a random force that we  take independent and identically distributed (iid) according to  a normal distribution with zero mean.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  10−2  100  x  10−5  100  P(x)/cx  1  2  1  3  1  4  k = 0 1 2  weibull  power  uniform  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Width of the stopping well, x, for different  Pw(w): a uniform, Weibull, and powerlaw distribution,  that scale as Pw(w) ∼ wk at small w, as indicated in the  legend (the bottom row for each distribution corresponds  to perturbing the dynamcs with random force kicks, tilt-  ing individual wells by a force F = N(0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1), with N the  normal distribution;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' the top row corresponds to F = 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  To emphasise the scaling, the distributions have been  rescaled by a fit of the prefactors: P(x) = cxxk+2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Fur-  thermore, we use m = κ = 1, η = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1, v0 = N(100, 10),  and ⟨w⟩ ≈ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  10−5  10−1  E  10−2  100  P(E)/ce  Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  The kinetic energy with which the particle  enters the well in which it stops for different realisations,  P(E), normalised by its prefactor ce (that is here simply  the density of the first bin).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' See Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' 4 for legend.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  5  References  [1] T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' de Geus, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Popovi´c, W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Ji, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Rosso, and  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Wyart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' How collective asperity detachments nucleate slip  at frictional interfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+page_content=' Acad.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+page_content='1906551116.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Fisher.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Collective transport in random media: From  superconductors to earthquakes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+page_content='1016/S0370-1573(98)00008-8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  arXiv: cond-mat/9711179.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [3] O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Narayan and D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Fisher.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Threshold critical dynamics of  driven interfaces in random media.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' B, 48(10):  7030–7042, 1993.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1103/PhysRevB.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='7030.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+page_content=' Kardar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Nonequilibrium dynamics of interfaces and lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Rep.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+page_content='  doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1016/S0370-1573(98)00007-6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  arXiv: cond-mat/9704172.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [5] M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' M¨uller and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Wyart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Marginal Stability in Structural,  Spin, and Electron Glasses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Annu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Condens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Matter  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=', 6(1):177–200, 2015.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1146/annurev-conmatphys-031214-014614.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [6] Alberto Rosso, James P Sethna, and Matthieu Wyart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Avalanches and deformation in glasses and disordered  systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' arXiv preprint: 2208.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='04090, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='48550/arXiv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='2208.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='04090.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [7] T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' de Geus and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Wyart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Scaling theory for the  statistics of slip at frictional interfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' E, 106  (6):065001, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1103/PhysRevE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='106.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='065001.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  arXiv: 2204.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='02795.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [8] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Prandtl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Ein Gedankenmodell zur kinetischen Theorie der  festen K¨orper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' angew.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Mech.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=', 8(2):85–106, 1928.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1002/zamm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='19280080202.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [9] G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Tomlinson.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' CVI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' A molecular theory of friction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The  London, Edinburgh, and Dublin Philosophical Magazine  and Journal of Science, 7(46):905–939, 1929.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1080/14786440608564819.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  [10] V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Popov and J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Gray.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Prandtl-Tomlinson Model: A  Simple Model Which Made History.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Stein, editor, The  History of Theoretical, Material and Computational  Mechanics - Mathematics Meets Mechanics and  Engineering, volume 1, pages 153–168.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Springer Berlin  Heidelberg, 2014.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' ISBN 978-3-642-39904-6  978-3-642-39905-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='1007/978-3-642-39905-3 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  A  Analytical solution  Anasatz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We look for the solution of a general lin-  ear equation of motion in one well  m¨r + η ˙r + κr − F = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (9)  where the position r is expressed relative to the local  minimum in potential energy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The external force F  tilts the potential energy landscape and will be used  as a perturbation to check the robustness of our ar-  gument.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' An ansatz to this differential equation is  r(τ) = αe−λ−τ + βe−λ+τ + ∆r,  (10)  where ∆r = F/κ, and τ is the time that the parti-  cle has spent since the entry in the current well at  r(τ = 0) ≡ −w/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We denote the particle’s veloc-  ity v(τ) ≡ ˙r(τ), whereby we take v(τ = 0) ≡ v0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Substituting this ansatz in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (9) leads to λ± =  (η ±  �  η2 − 4mκ)/(2m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The prefactors α and β are  set by the initial conditions such that  α, β = ±r0λ± + v0  λ+ − λ−  ,  (11)  with r0 ≡ −w/2 − ∆r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Underdamped.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We recognise that if λ± are real  (η2 > 4mκ), the dynamics are overdamped and the  velocity decays exponentially.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Conversely, the un-  derdamped dynamics that we consider correspond to  η2 < 4mκ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Oscillator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  In the underdamped case, λ± and α, β  are complex conjugates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' This allows us to simplify  the solution by expressing those coefficients as λ± =  λ ± iω and α, β = (L/2)e±iφ as follows 4  r(τ) = Le−λτ cos(ωτ + φ) + ∆r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (12)  We remark that the velocity v(τ) can be expressed as  a phase shift with respect to r(τ) 5  v(τ) = −Ae−λτ cos  �  ωτ + φ − arctan  �ω  λ  ��  (13)  with A = λL  �  1 + (ω/λ)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We summarise the ampli-  tudes, frequency, and phase.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' From λ± we find  λ =  η  2m,  ω2 = κ  m −  � η  2m  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (14)  Furthermore, Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (11) gives  α, β = 1  2  �  r0 ∓ i(λr0 + v0)/ω  �  ,  (15)  such that  L2 = 4  �  Re(α)2 + Im(α)2�  (16)  =  �  (ωr0)2 + (λr0 + v0)2�  /ω2,  (17)  and  φ = χπ + arctan (Im(α)/Re(α))  (18)  = χπ − arctan (λ/ω + v0/(ωr0)) ,  (19)  where χ depends on α 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  3Note that our solution warrants some caution for critical  damping η2 = 4mκ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  4cos(z) = (eiz + e−iz)/2  5a cos(z) + b sin(z) = sgn(a)  √  a2 + b2 cos (z − arctan(b/a))  6Re(α) ≥ 0 → χ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (Re(α) < 0, Im(α) ≥ 0) → χ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (Re(α) < 0, Im(α) < 0) → χ = −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  6  B  Exiting well  We will show that the minimum kinetic energy with  which the particle needs to enter a well to be able  to exit Ec ∝ w2, whereby we consider F = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The  particle exits the well if v0 > vc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' vc thus corresponds  to the case that r(τe) = w/2 = −r0 for which v(τe) =  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' Let us make the ansatz that v0 = vc = w/τc and  look for the solution of τc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  We note that on the interval τ ∈ [0, τe) the posi-  tion is strictly monotonically increasing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' The solution  of v(τn) = 0 corresponds to  ωτn + φ − arctan(ω/λ) = (n + 1/2)π,  n ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (20)  The for us relevant solution is τe = min(τn > 0) 7 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  r(τe) = w/2 corresponds to  Le−λτe = w/(2c0),  (21)  with  c0 = cos((n + 1/2)π + arctan(ω/λ)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (22)  Using the definition of τe in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (20) leads to  Leλφ/ω = w/(2c0c1),  (23)  with  c1 = e−λ(n+1/2)π/ω−(λ/ω) arctan(ω/λ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (24)  Furthermore,  L2 = 1  4  �  ω2 + (2/τc − λ)2�  (w/ω)2,  (25)  φ = sign (2/τc − λ) π + arctan  ��  2/τc − λ  �  /ω  �  , (26)  such that  L′eλφ/ω = 1/(2c0c1),  (27)  with L′ = L/w.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (27) is w independent and can  be solved for τc = τc(λ, ω, n), proving that vc = w/τc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  This results thus corresponds to  Ec = 1  2mv2  c = m  2τ 2c  w2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (28)  as we used to go from Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (2) to obtain Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (4) using  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  7i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' n = ±1 depending on (r0, v0)  C  Entry kinetic energy  With K the kinetic energy at exiting the well, we show  that ∂wK  ��  w=w∗ > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' We again consider F = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' In  particular, we show that  ∂wK = m ve ∂wve > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (29)  The derivative of the velocity as a function of the well  size is  ∂rv = ∂τv/∂τr = a(τ)/v(τ),  (30)  where the acceleration a(τ) ≡ ¨r(τ) = αλ2  −e−λ−τ +  βλ2  +e−λ+τ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' By evaluating this expression with initial  conditions r(τ = 0) = −w∗/2 and v(τ = 0) = 0, we  find  ∂wK  ��  w=w∗ = m (αλ2  − + βλ2  +) = −m  2 (λ2 + ω2) w∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content='  (31)  From the definitions of λ and ω in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (14), we thus  find  ∂wK  ��  w=w∗ = −κw∗/2,  (32)  as we argued above to show that P(E = 0) > 0 using  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
+page_content=' (8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/-dFST4oBgHgl3EQfcTgr/content/2301.13802v1.pdf'}
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+1
+Adaptive Resource Allocation for Workflow
+Containerization on Kubernetes
+SHAN Chenggang, WU Chuge, XIA Yuanqing,GUO Zehua,LIU Danyang, and ZHANG Jinhui
+Abstract—In a cloud-native era, the Kubernetes-based workflow engine enables workflow containerized execution through the inherent
+abilities of Kubernetes. However, when encountering continuous workflow requests and unexpected resource request spikes, the
+engine is limited to the current workflow load information for resource allocation, which lacks the agility and predictability of resource
+allocation, resulting in over and under-provisioning resources. This mechanism seriously hinders workflow execution efficiency and
+leads to high resource waste. To overcome these drawbacks, we propose an adaptive resource allocation scheme named ARAS for
+the Kubernetes-based workflow engines. Considering potential future workflow task requests within the current task pod’s lifecycle, the
+ARAS uses a resource scaling strategy to allocate resources in response to high-concurrency workflow scenarios. The ARAS offers
+resource discovery, resource evaluation, and allocation functionalities and serves as a key component for our tailored workflow engine
+(KubeAdaptor). By integrating the ARAS into KubeAdaptor for workflow containerized execution, we demonstrate the practical abilities
+of KubeAdaptor and the advantages of our ARAS. Compared with the baseline algorithm, experimental evaluation under three distinct
+workflow arrival patterns shows that ARAS gains time-saving of 9.8% to 40.92% in the average total duration of all workflows, time-saving
+of 26.4% to 79.86% in the average duration of individual workflow, and an increase of 1% to 16% in CPU and memory resource usage
+rate.
+Index Terms—Resource Allocation, Workflow Containerization, Kubernetes, Workflow Management Engine.
+!
+1
+INTRODUCTION
+W
+ITH the advent of a cloud-native era, the most
+popular virtualization solution is using Docker
+1
+for container encapsulation with Kubernetes (K8s) [1] for
+multi-host container orchestrating. Docker and K8s 2 have
+become mainstream tools for cloud resource management
+and dominated the whole cloud-native technology ecosys-
+tem [2]. Workflows have been widely applied in scientific
+computing communities such as astronomy, bioinformatics,
+material science, and earth science [3]. A scientific workflow
+is commonly formulated as a directed acyclic graph (DAG),
+which consists of dozens of workflow tasks (represented
+by nodes) and dependencies among tasks (indicated by
+directed edges). A DAG abstracts a particular scientific
+computing process through shared data files between tasks
+and predefined task dependencies [4], [5]. Powered by
+Docker and K8s, cloud infrastructure features the scalability
+and high availability of computational resources [6] and
+is especially suitable as a running platform for scientific
+workflows.
+Scientific workflows usually serve large-scale applica-
+tions and require a considerable amount of resources to
+execute. Efficient resource allocation is a key issue in work-
+•
+C. Shan and D. Liu are with the School of Automation, Beijing Institute
+of Technology, Beijing 100081, China. C. Shan is also with the School of
+Artificial Intelligence, Zaozhuang University, Zaozhuang 277100, China.
+E-mail: {uzz scg, liudanyang093}@163.com
+•
+C. Wu, Y. Xia, Z. Guo and J. Zhang are with the School of Automation,
+Beijing Institute of Technology, Beijing 100081, China. E-mail: {wucg,
+xia yuanqing, guo, zhangjinh}@bit.edu.cn
+(Corresponding author: Jinhui Zhang)
+1. http://docs.docker.com
+2. https://kubernetes.io/
+flow execution. Existing workflow management engines
+like Nextflow [7], Pagasus [8], [9], Galaxy [10], and Argo
+workflow engine
+3 can execute hundreds of workflows
+on cloud infrastructure and be responsible for assigning
+computational resources to workflow tasks [11]. When en-
+countering continuous workflow requests and unexpected
+resource request spikes, the computational resource require-
+ments of workflows can be highly dynamic. The ever-
+changing resource requirements of workflows bring a great
+administrative burden to the workflow engines for resource
+allocation and seriously decrease the execution efficiency of
+workflows. On the one hand, the permanent provision of
+fixed computational resources will cope with peak loads in
+a resource-intensive scenario but incur high costs and re-
+source over-provisioning, as resources are not fully utilized
+during off-peak times. On the other hand, some workflows
+may not be executed at all and suffer from a poor Quality of
+Service (QoS) due to insufficient resource provisions.
+In order to avoid over and under-provisioning of re-
+sources, some existing works propose reasoning [12], [13],
+feedback [14], heuristics [15], learning and prediction mod-
+els [16], [17], [18], [19] to cope with resource allocation in
+cloud environment. Although these solutions can partially
+address the cloud resource allocation problem, they com-
+monly use prior knowledge of cloud systems to cope with
+resource allocation. As a result, these solutions might play
+to their strengths in a specific application scenario, but they
+are not fully adaptable to the K8s-based cloud environment
+with dynamic resource requirements. Besides, numerous it-
+eration training may result in high computational complex-
+ity and resource overheads in learning and prediction mod-
+3. http://github.com/argoproj/argo
+arXiv:2301.08409v1  [cs.DC]  20 Jan 2023
+
+2
+els. Therefore, with the application platform and technology
+stack in mind, they do not fit with the K8s-based workflow
+management engines. The bottleneck here is the absence of a
+high-efficiency adaptive resource allocation scheme that can
+help the K8s-based workflow management engines to make
+appropriate resource provisions in response to continuous
+workflow requests and unexpected request resource spikes.
+In
+our
+former
+work
+[20],
+[21],
+we
+presented
+the customized K8s-based
+workflow
+management
+en-
+gine (KubeAdaptor), able to integrate workflow systems
+with K8s and implement workflow containerization on K8s
+cluster. In this paper, we present an adaptive resource alloca-
+tion scheme (ARAS) that follows the Monitor-Analyse-Plan-
+Execute Knowledge (MAPE-K) model [22], [23]. The ARAS
+periodically responds to the task pod’s resource request and
+uses the resource discovery algorithm, resource evaluation
+algorithm, and resource allocation algorithm to complete
+the resource allocation of this round task by the resource
+scaling strategy. We reconstruct and extend KubeAdaptor,
+and implement ARAS as the Resource Manager component
+of KubeAdaptor, which consists of a Resource Discovery
+module, Resource Evaluator module, and Allocator mod-
+ule. Three modules complement each other to achieve the
+adaptive resource allocation (refers to Fig. 2). First, the
+Resource Discovery module invokes the resource discovery
+algorithm to obtain the remaining resources (such as CPU
+and memory) of K8s cluster nodes and the resource usage
+of running task pods. Then the Resource Evaluator module
+integrates the remaining resources of the K8s cluster and
+workflow workloads from the Redis database and evalu-
+ates resource adequacy for the K8s cluster nodes. Finally,
+the Allocator module uses a resource scaling strategy (i.e.,
+vertical autoscaling) [24] to make resource provisions for
+current active task pods in response to continuous workflow
+requests and sudden request spikes. We have open-sourced
+the proposed ARAS. The source code is publicly available
+on GitHub 4.
+This paper focuses on adaptation, that is, the adap-
+tive adjustment of resource allocation in the context of
+changing workflow resource requirements. Compared with
+the baseline algorithm, experimental evaluation of running
+four scientific workflows under three different workflow
+arrival modes shows that ARAS gains time-saving of 9.8%
+to 40.92% in the average total duration of all workflows,
+time-saving of 26.4% to 79.86% in the average duration of
+individual workflow, and an increase of 1% to 16% in CPU
+and memory resource usage rate. The main contributions of
+this paper are summarized as follows.
+•
+MAPE-K architecture. With the MAPE-K mecha-
+nism
+as
+a
+core,
+we
+decouple
+and
+reconstruct
+the KubeAdaptor and integrate our ARAS into
+four
+phases
+of
+the
+MAPE-K
+model
+to
+equip
+the
+KubeAdaptor
+with
+self-healing
+and
+self-
+configuration abilities.
+•
+A novel monitoring mechanism. We devise and de-
+velop a resource discovery algorithm through the
+K8s resource characteristics and Informer component.
+The Resource Discovery module uses this algorithm
+4. https://github.com/CloudControlSystems/ResourceAllocation
+to build a novel monitoring mechanism to collect all
+related data in K8s clusters.
+•
+Automation deployment. We modularize and imple-
+ment the four steps of the proposed ARAS with loose
+coupling in mind so that the users can easily mount
+a newly designed algorithm module to replace an ex-
+isting one with minimal intrusion into the workflow
+management engine.
+•
+Better performance. With the help of K8s and the
+MAPE-K mechanism, we use ARAS to conduct a
+wealth of experiments on four scientific workflows
+on K8s clusters. Our ARAS shows better perfor-
+mance compared to the baseline algorithm.
+The rest of the paper is organized as follows. Section 2
+introduces related work. Section 3 elaborates on the system
+model and problem formulation, while Section 4 further
+describes our system architecture and components. Section
+5 illustrates the implementation of our adaptive resource
+allocation scheme. Section 6 describes the experimental
+setup and discusses the evaluation results. Finally, Section
+7 concludes this paper.
+2
+RELATED WORK
+The resource allocation scheme in the workflow manage-
+ment engine is influenced by the virtualization technology
+of cloud infrastructure, which is directly related to whether
+workflow tasks are hosted by VM instances or containers.
+In this section, we review the development of resource
+allocation strategy and discuss three categories of resource
+allocation strategy from the perspective of the evolution
+of virtualization technology, namely VM-based, Container-
+based, and Cloud-native-based. Note that the analysis of
+each aspect is not completely limited to the scope of the
+workflow management engine.
+2.1
+VM-based resource allocation
+In the VM-based era, Lee et al. [25] propose an adap-
+tive scheduling approach to adjust resource allocation and
+scheduling in the Pegasus workflow management system.
+This approach utilizes batch queues to assign jobs to clus-
+ter’s VMs and optimizes job scheduling across cluster’s
+VMs through the average queue time of each available
+VM. Islam et al. [26] develop prediction-based resource
+measurement and provisioning strategies using neural net-
+works and linear regression to satisfy upcoming resource
+demands. The sliding window approach for predicting re-
+source usage in the cloud fits with dynamic and proactive
+resource management for interactive e-commerce applica-
+tions. As for Business Process Management System (BPMS)
+field, Hoenisch et al. [12] present a self-adaptive resource
+allocation approach to automatically lease and release cloud
+resources for workflow executions based on knowledge (re-
+source usage in VMs) about current and future process
+landscape. This approach has been implemented as part of
+ViePEP, a BPMS able to manage and schedule workflows
+in the cloud. By monitoring resource usage of VMs and
+the QoS of individual service invocations in VMs, ViePEP
+uses a prediction model to provide resource provisioning
+for elastic process execution of workflows. Subsequently,
+
+3
+Hoenisch et al. [13] extend ViePEP by dynamic workflow
+scheduling and resource allocation algorithms. The pro-
+posed algorithm not only provides a complete schedule plan
+based on their former predicting model but also moves the
+service invocations (workflow task) from one timeslot to
+another to fully utilize the acquired resources.
+Although these solutions present appropriate cloud re-
+source allocation schemes to some extent, the predictive
+models commonly require the collection and modeling ac-
+cording to former data. These upfront preparations consume
+unnecessary resources and block the automatic operation
+flow of the workflow management engines. Besides, VMs-
+based resource allocation schemes are commonly limited to
+VM’s features such as slow startup, clumsy deployment,
+and high resource consumption. Therefore, these schemes
+are not suitable for performing workflows with dynamic
+and ever-changing resource requirements in cloud infras-
+tructures.
+2.2
+Container-based resource allocation
+In the Container era, container-based resource allocation
+schemes gradually become the mainstream of cloud re-
+source management. Considering the absolute resource iso-
+lation and security features of VMs, most container-based
+resource allocation scenarios adopt the deployed model of
+VM hosting containers. For instance, Mao et al. [27] propose
+a differentiated quality of experience scheduler to adjust
+resource provisioning for deep learning applications. This
+scheduler is implemented into Docker Swarm 5 and can
+accept the targeted quality of experience specifications from
+clients and dynamically adjust resource limits of contain-
+ers to approach performance targets. Abdullah et al. [16]
+introduce a new deep learning-based approach to estimate
+the execution time of the jobs through the collected per-
+formance traces. This approach also predicts the execution
+time for different CPU pins and uses the laws of dimin-
+ishing marginal returns to provide optimal CPU allocation
+to Docker containers. In the fog computing community,
+Yin et al. [28] propose a container-based task-scheduling
+algorithm with task delay constraint in mind. Herein, a
+resource reallocation mechanism works to achieve resource-
+utilization maximization on fog nodes by modifying the re-
+source quota of task containers. Hu et al. [29] propose CEC,
+a containerized edge computing framework for dynamic
+resource provisioning in response to multiple intelligent
+applications. The CEC first makes resource provisioning for
+containers in advance based on the workload prediction
+for the edge cluster formed by Docker Swarm and then
+uses the idea of control theory to achieve dynamic resource
+adjustments (meaning a sufficient number of containers) for
+hosted service applications.
+Containers, an efficient and lightweight virtualization
+technology, bring significant technology change to VMs-
+based resource allocation strategies. But in fact, it needs a
+container orchestration tool (e.g., Docker Swarm) to manage
+a wealth of containers across cluster nodes in several sce-
+narios. In practice, resource limits’ adjustment and realloca-
+tion of resource quotas in running containers have brought
+significant administrative burdens to Docker Swarm. Also,
+5. https://docs.docker.com/engine/swarm/
+the adjustments to the number of containers will cause a
+delay in the startup of new containers. In addition, the
+preparation for predictive models is also not conducive
+to the automation of workflow management engines. Due
+to the shortcomings of the above solutions and the task
+dependencies and high concurrency of workflow, these re-
+source allocation strategies can not provide efficient ideas
+for container-based workflow management engines.
+2.3
+Cloud-native-based resource allocation
+As the first hosted project by Cloud Native Computing
+Foundation (CNCF) 6, K8s has become the de-facto standard
+container orchestration system. Docker and K8s are reshap-
+ing resource management strategies for cloud infrastruc-
+tures in the cloud-native era. For example, Chang et al. [30]
+propose a generic platform to facilitate dynamic resource
+provisioning based on K8s. The platform employs open-
+source tools to retrieve all the resource utilization metrics
+(such as CPU and memory) while integrating the applica-
+tion QoS metrics into monitoring. The resource scheduler
+module in the platform makes dynamic resource provi-
+sioning by horizontal scaling of task pods according to
+the K8s cluster’s workload. Mao et al. [31] investigate the
+performance of using cloud-native frameworks (Docker and
+K8s) for big data and deep learning applications from the
+perspective of resource management fields. Together with
+Prometheus 7 and Grafana 8, the authors build a container
+monitoring system to keep tracking the resource usage of
+each job on worker nodes. To address massive aggregate re-
+source wastage, Google uses Autopilot to configure resources
+automatically, adjusting both the number of concurrent
+tasks in a job (horizontal scaling) and the CPU/memory lim-
+its for individual tasks (vertical scaling) [24]. Subsequently,
+Bader et al. [11] propose Tarema, a system for allocating task
+instances to heterogeneous K8s cluster resources during the
+execution of scalable scientific workflows. Using a scoring
+algorithm to determine the best match between a task and
+the available resources, Tarema provides the near-optimal
+task-resource allocation.
+However, most of these resource allocation solutions
+in the cloud-native era use open source tools (from the
+CNCF community) to build resource monitoring systems,
+obtain the required resource utilization of the cluster, and
+provide corresponding resource provisioning strategies. It
+brings high deployment costs to the workflow management
+engine, which is inconsistent with the simple deployment
+and automatic system characteristics. In addition, these
+tools put too much pressure on the K8s cluster because
+of frequent access to kube-apiserver 9 for acquiring cluster
+resources [32].
+To summarize the related work, we can conclude that
+resource allocation policies change with the evolution of
+virtualization technologies to adapt to different application
+scenarios and technology platforms. The most typical exam-
+ple is ViePEP-C [33], which evolved from former work [12],
+6. https://www.cncf.io/
+7. https://github.com/prometheus/prometheus
+8. https://github.com/grafana/grafana
+9. The API server serves as the front end and is a component of
+the K8s control plane that exposes the K8s API. Its performance is a
+weathervane for the overall K8s cluster performance.
+
+4
+[13], [34], [35] in the VMs era to a container-based resilient
+BPMS platform in the container era, using containers in-
+stead of VMs for the execution of business process activ-
+ities. Considering automation and flexible deployment of
+the integrated platform, resource allocation technology in
+the cloud-native era is more focused on Docker and K8s
+platforms. The design of our workflow management engine
+follows this idea. K8s, with its unique technical advantages
+and ecology in scheduling, automatic recovery, horizontal
+scalability, resource monitoring, and other aspects, makes its
+integration with workflow management engines far beyond
+the capabilities of container-based workflow management
+engines. Inspired by the work in [24], [27], [31], our ARAS
+takes into account workflow loads in K8s clusters and
+uses vertical scaling technology of containers to cope with
+continuous workflow requests and sudden resource spikes.
+3
+SYSTEM MODEL
+This section describes how to use our ARAS to cope with
+continuous workflow requests and unexpected resource re-
+quest spikes and maximize resource utilization while meet-
+ing workflow Service Level Objectives (SLOs).
+3.1
+System description
+For the clarity of presentation, we consider the scenario of
+a single K8s cluster with a set of nodes (VMs), donated by
+V = {v1, v2, ..., vm}, where m represents the number of K8s
+cluster nodes. As for m nodes, we have a set of available
+CPU cores C = {c1, c2, ..., cm} and a set of availble memory
+capacity M = {mem1, mem2, ...memm} correspondingly.
+The workflow set injected into the KubeAdaptor is rep-
+resented as W = {w1, w2, ..., wk}, where k indicates the
+amount of workflows. Herein, a workflow is abstractly
+defined as wi = {slawi, si,1, si,2, ..., si,n}, wherein i in-
+dicates the ID of a workflow, slawi represents a Service
+Level Agreement (SLA) of a workflow and si,1, si,2, ..., si,n
+indicates steps (i.e., tasks) of workflow wi. Each workflow
+task is defined as
+si,j = {slasi,j, id, image, cpu, mem, duration,
+mincpu, minmem}, 1 ≤ i ≤ k and 1 ≤ j ≤ n.
+(1)
+Herein, id is the unique identifier of this workflow task
+in workflow wi, and image represents the Docker Image
+address of this workflow task. The cpu is the amount of
+CPU Milli cores required by the users, and mem is the
+amount of memory capacity required by the users. duration
+indicates the duration of the task pod running, and mincpu
+and minmem represent a minimum of CPU and memory
+resources required to run the task container of si,j in work-
+flow wi, respectively. Generally, a workflow can have an
+optional SLA (slai) composed of several SLOs expressed
+by slo1, slo2, ..., slon on workflow (slawi) or workflow
+task (slasi,j) as following:
+slai = {slo1, slo2, ..., slon}, i ∈ {wi, si,j}.
+(2)
+Herein, we only consider the deadline as the single SLO,
+meaning that each task in the workflow must be completed
+before its respective deadlines. Likewise, this workflow is
+no exception.
+slawi = deadlinewi,
+slasi,j = deadlinesi,j.
+(3)
+Note that the deadline for the last task si,last in a workflow
+is identical to this workflow execution deadline:
+deadlinesi,last = deadlinewi.
+(4)
+3.2
+Problem formulation
+We assume that SLAs and deadlines defined by users are
+valid and achievable, i.e., a properly completed workflow
+means that all of its tasks must be completed by the
+deadline. With maximizing the resource utilization in the
+K8s cluster as a goal, as long as a task request arrives,
+our ARAS uses the resource scaling method to provide
+computational resources to the task container. Herein, the
+resource provision of the task container must not be less
+than a minimum of running resources to ensure the smooth
+operation of the task container.
+Fig. 1 depicts an execution process of a small-scale Mon-
+tage workflow. At t1 seconds, task request of T1 arrives, and
+our ARAS has abilities to acquire concurrent tasks within its
+lifecycle (from t1 to t2) considering predefined deadlines. As
+can seen from Fig. 1, T2, T3 and T4 will be launched within
+T1’s lifecycle and four workflow tasks will compete for com-
+puting resources each other. To ensure that four concurrent
+tasks have enough resources to run smoothly, our ARAS
+employs the resource scaling method to reasonably allocate
+resources, i.e., scaling down resource requirements of the
+current task T1 according to the ratio of the total resource
+requirements of four tasks to the remaining resources in the
+K8s cluster (refers to Eq. (9)). Similarly, T10 executes between
+t2 and t3, T16 executes between t4 and t5. Their respective
+lifecycle all contains several concurrent tasks. The arrival of
+each task request also requires the resource scaling method
+to allocate resources in line with Eq. (9).
+In the following, we elaborate on the optimal problem
+in our ARAS. The allocated CPU and memory resources for
+each requested task in workflow wi are respectively defined
+as follows:
+U = {ui,1, ui,2, ..., ui,n},
+R = {ri,1, ri,2, ..., ri,n}.
+(5)
+xi
+y,z ∈ {0, 1} with workflow identifier i is adopted as a
+decision variable for task placement, where 1 ≤ y ≤ n and
+1 ≤ z ≤ m and defined as
+xi
+y,z =
+�
+1
+if yth task in wi is scheduled on Node vz,
+0
+if yth task in wi is not scheduled on Node vz.
+We assume that each node in the K8s cluster is always
+active and that workflows are continuously injected into
+our workflow management engine. Memtotal indicates the
+total number of remaining memory resources of the K8s
+cluster. Since CPU is a compressible resource and memory
+is an incompressible resource, we only consider memory to
+maximize resource allocation in the optimization model. So
+our objective function is as follows:
+
+5
+(S)
+0
+t1
+Node1
+Node2
+Node3
+Node4
+Node5
+Node6
+Node1
+Node2
+Node3
+Node4
+Node5
+Node6
+T0
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T17
+T18
+T19
+T20
+t2
+t3
+t4
+t5
+  task  container
+VM (K8s Cluster Node)
+Legend:
+(S)
+0
+t1
+Node1
+Node2
+Node3
+Node4
+Node5
+Node6
+T0
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T17
+T18
+T19
+T20
+t2
+t3
+t4
+t5
+  task  container
+VM (K8s Cluster Node)
+Legend:
+Fig. 1. Resource allocation example. A small-scale Montage workflow
+with 21 tasks is used to illustrate the resource scaling method in our
+ARAS. The test environment uses our experimental setup in Sec-
+tion 6.1.1.
+Maximize :
+k
+�
+i=1
+n
+�
+j=1
+ri,j/Memtotal
+(6)
+Subject to:
+m
+�
+z=1
+xi
+y,z = 1
+k
+�
+i=1
+n
+�
+y=1
+xi
+y,j · ui,y ≤ cj
+k
+�
+i=1
+n
+�
+y=1
+xi
+y,j · ri,y ≤ memj.
+(7)
+Eq. (6) shows the objective function in our model, which
+maximizes the resource utilization for the remaining mem-
+ory of the K8s cluster at each moment of the task request.
+Eq. (7) shows three constraints of our model. The first
+constraint indicates that a task can be scheduled on only one
+cluster node. The last two constraints imply that the total
+CPU and memory resources consumed by all task pods on
+the hosted node vj must be less than or equal to the amount
+of the respective available resources on that node.
+4
+ARCHITECTURE
+This section presents the system architecture of KubeAdap-
+tor in detail, including its framework, design logic, and key
+modules. Subsequently, the MAPE-K model is elaborated
+around the resource allocation mechanism of KubeAdaptor.
+4.1
+KubeAdaptor framework
+The KubeAdaptor for the ARAS is illustrated in Fig. 2. As
+a workflow management engine, it works to administrate,
+schedule, and execute containerized workflow tasks. Its core
+functionalities are as follows:
+•
+Provide an interface to the public or private cloud,
+allowing to customize workflows on demand
+•
+Implement the containerized execution of workflows
+following the precedence and dependency relation-
+ships
+•
+Adaptively allocate resource quotas for requested
+workflow tasks and maximize resource utilization
+when ensuring the SLAs of workflows
+•
+Provide the ability of flexible deployment and the
+automatic operation flow and integrate into the K8s
+platform
+With the assistance of ARAS in this paper, KubeAdaptor
+equips with the functionalities of a cloud resource man-
+agement system to elegantly manage a potentially highly
+volatile cloud workflow application scenario.
+4.2
+KubeAdaptor modules
+As depicted in Fig. 2, KubeAdaptor consists out of three
+main top level entities, including a Command Line Inter-
+face (CLI), a Workflow Injection Module and a Containerized
+Workflow Builder. The Containerized Workflow Builder com-
+prises seven sub-components responsible for workflow re-
+ception, containerization, resource allocation, resource mon-
+itoring, and task container cleanup. We focus on the Resource
+manager module related to ARAS.
+CLI: It aims to define SLAs-based workflows and offer
+configuration files of one-key deployment. In addition, the
+users may request many workflows consecutively or even
+simultaneously through the CLI module.
+Workflow Injection Module: Its Parser and Packaging
+modules serve as an independent function pod and work
+to read variable configuration information of workflow def-
+inition from the mounted directory, parse and encapsulate
+workflows in response to generating request of the subse-
+quent workflow from the Interface Uint.
+Interface Uint: This module works on receiving the
+workflow generating request, decomposing the workflow
+tasks, watching the state changes of task pods or workflows
+from the Task Container Cleaner, invoking the Containerized
+Executor to generate workflow namespaces and task pods,
+and writing workflow status into the Redis database. Once
+the creation of the task pod fails, this module turns to fault
+tolerance management [21], also known as self-healing, the
+ability of a system to detect and recover from potential
+problems and continue to operate smoothly.
+Containerized Executor: Its two subcomponents work
+on generating workflow namespaces and task pods. This
+module creates task pods through allocated resources from
+the Resource Manager. In addition, the states of workflows
+and task pods are timely written into the Redis database.
+Resource Manager: It contains three subcomponents,
+such as Resource Discovery, Resource Evaluator and Alloca-
+tor. The Resource Discovery is responsible for acquiring the
+remaining resource of the overall K8s cluster from the
+Informer. The Resource Evaluator obtains workflow resource
+requirements and workflow execution states from the Redis
+database, assesses the adequacy of the current remaining
+resources of the K8s cluster, and launches corresponding
+countermeasures, if necessary. The Allocator module uses
+resource scaling strategy to make resource allocation for
+current active task pods in response to continuous workflow
+requests and sudden request spikes. It is also known as
+self-configuration, the ability of a system to reconfigure itself
+under changing and unpredictable circumstances.
+Informer: As a core toolkit in Client go 10, the Informer
+is in charge of synchronizing resource objects and events
+10. https://github.com/kubernetes/client-go
+
+6
+                                 
+Workflow 
+Injection 
+Module
+Parser
+Packaging
+config.yaml
+wf.yaml
+...
+Command Line 
+Interface (CLI)
+Interface 
+Unit
+Namespace 
+Creator
+Task Container
+Creator
+Containerized Executor
+Volume
+Volume
+Resource 
+Discovery
+Resource 
+Evaluator
+Allocator
+Resource Manager
+Redis 
+State Tracker
+Task Container 
+Cleaner
+Node n
+task pod
+. . .
+Node n
+task pod
+. . .
+task pod
+task pod
+Node n
+task pod
+. . .
+task pod
+task pod
+K8s Cluster
+Node 2
+task pod
+. . .
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+Node 1
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+task pod
+task pod
+. . .
+Node n
+task pod
+. . .
+task pod
+task pod
+K8s Cluster
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+task pod
+task pod
+. . .
+Node n
+task pod
+. . .
+task pod
+task pod
+K8s Cluster
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+task pod
+task pod
+. . .
+KubeAdaptor
+Containerized Workflow Builder
+Informer
+                                 
+Workflow 
+Injection 
+Module
+Parser
+Packaging
+config.yaml
+wf.yaml
+...
+Command Line 
+Interface (CLI)
+Interface 
+Unit
+Namespace 
+Creator
+Task Container
+Creator
+Containerized Executor
+Volume
+Resource 
+Discovery
+Resource 
+Evaluator
+Allocator
+Resource Manager
+Redis 
+State Tracker
+Task Container 
+Cleaner
+Node n
+task pod
+. . .
+Node n
+task pod
+. . .
+task pod
+task pod
+Node n
+task pod
+. . .
+task pod
+task pod
+K8s Cluster
+Node 2
+task pod
+. . .
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+Node 1
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+task pod
+task pod
+. . .
+Node n
+task pod
+. . .
+task pod
+task pod
+K8s Cluster
+Node 2
+task pod
+. . .
+task pod
+task pod
+Node 1
+task pod
+. . .
+task pod
+task pod
+. . .
+KubeAdaptor
+Containerized Workflow Builder
+Informer
+Fig. 2. KubeAdaptor architecture.
+Monitoring
+Analysis
+Planning
+Execution
+Remaining resources and
+workflow  status
+Allocated resources
+New plan
+Informer
+Redis 
+Remaining 
+resources and 
+workflow status
+K8s Cluster
+Workflow Injection 
+Module
+Interface 
+Unit
+Containerized 
+Executor
+Command Line 
+Interface (CLI)
+deploy
+Resource Manager
+State Tracker
+Task Container 
+Cleaner
+Concrete workflow
+Resource Allocation
+Delete completed task
+Abstract workflow
+Watch resource 
+objects
+Synchronize 
+resource status
+Trigger 
+next task
+Create task 
+pods
+Workflow Status
+Write workflow 
+data
+Acquire
+resources
+MAPE-K Model
+Update 
+workflow 
+data
+Watch task
+ pod
+Monitoring
+Analysis
+Planning
+Execution
+Remaining resources and
+workflow  status
+Allocated resources
+New plan
+Informer
+Redis 
+Remaining 
+resources and 
+workflow status
+K8s Cluster
+Workflow Injection 
+Module
+Interface 
+Unit
+Containerized 
+Executor
+Command Line 
+Interface (CLI)
+deploy
+Resource Manager
+State Tracker
+Task Container 
+Cleaner
+Concrete workflow
+Resource Allocation
+Delete completed task
+Abstract workflow
+Watch resource 
+objects
+Synchronize 
+resource status
+Trigger 
+next task
+Create task 
+pods
+Workflow Status
+Write workflow 
+data
+Acquire
+resources
+MAPE-K Model
+Update 
+workflow 
+data
+Watch task
+ pod
+KubeAdaptor
+Monitoring
+Analysis
+Planning
+Execution
+Remaining resources and
+workflow  status
+Allocated resources
+New plan
+Informer
+Redis 
+Remaining 
+resources and 
+workflow status
+K8s Cluster
+Workflow Injection 
+Module
+Interface 
+Unit
+Containerized 
+Executor
+Command Line 
+Interface (CLI)
+deploy
+Resource Manager
+State Tracker
+Task Container 
+Cleaner
+Concrete workflow
+Resource Allocation
+Delete completed task
+Abstract workflow
+Watch resource 
+objects
+Synchronize 
+resource status
+Trigger 
+next task
+Create task 
+pods
+Workflow Status
+Write workflow 
+data
+Acquire
+resources
+MAPE-K Model
+Update 
+workflow 
+data
+Watch task
+ pod
+KubeAdaptor
+Fig. 3. Resource allocation scheme based on MAPE-K model.
+between K8s core components and Informer local cache.
+It provides the Resource Discovery with the remaining re-
+sources of the K8s cluster and responds to the State Tracker
+for the state changes of the resource objects.
+State Tracker: It hosts the monitoring program based
+on the List-Watch mechanism and responds state queries of
+various resource objects to each module anytime.
+Task Container Cleaner: It works on deleting the pods
+in a state of Succeeded or Failed or OOMKilled and workflow
+namespaces without uncompleted task pods. Once receiving
+successful feedback on the just-deleted workflow or task
+pods, this module proceeds to Interface Unit and triggers
+the following workflow or subsequent task.
+Redis: The Redis database is to be deployed within
+or outside the cluster in advance and is responsible for
+storing workflow execution status and predefined resource
+requirements of workflow tasks.
+KubeAdaptor is implemented by the Go language and
+provides an CLI interface to K8s clusters. With just a few
+tweaks to the configuration file, the users can go out of
+the box and smoothly deploy the KubeAdaptor on K8s
+clusters. The deployment and uninstalling of KubeAdaptor
+are non-intrusive and clean to the cluster, and its workflow
+containerization execution works in an automated way. For
+further details about KubeAdaptor, we refer to [21].
+4.3
+MAPE-K model
+The MAPE-K model [36], originated from the field of Auto-
+matic Computing, is an instrumental framework for system-
+atic development of adaptive systems, including resource al-
+location and workflow adaptation. Adaptive strategy within
+the KubeAdaptor works to realize the self-optimization
+of resource utilization maximization. Herein, the self-
+optimization ability, along with self-healing and self-
+configuration (elaborated in 4.2), enables our KubeAdaptor
+to become a self-management system.
+To deal with persistent workflow requests and ever-
+changing resource requirements, we use the MAPE-K model
+to retrofit with minimal intervention to the KubeAdaptor,
+which forms an adaptive execution cycle as depicted in
+Fig. 3. In the following, we will briefly discuss the four steps
+of this cycle and how they influence the self-management
+capabilities of KubeAdaptor:
+Monitoring: The Monitoring functionalities stem from
+the Informer and Redis database and work to provide work-
+flow status and the remaining resources in K8s Clusters
+to the next step. Workflow status data includes which
+workflows have been executed, which tasks have been com-
+pleted, resource requirements of workflow tasks, as well as
+the SLOs of the workflow and task. The remaining resources
+refer to the residual CPU and memory resources of the K8s
+cluster and each node in the K8s cluster.
+Analysis: The functionality of this step comes into play
+in the Resource Evaluator and Allocator within Resource Man-
+ager. For adaptive resource allocation, it is necessary to
+analyze the monitored data and reason on the general
+knowledge about the system. It is done so that we can
+adapt according to countermeasures to deal with dynamic
+workflow requests and SLA violations.
+Planning: The planning step takes full account of the
+resource requirements for future workflow tasks to be
+launched within the current task lifecycle and SLAs of
+workflows to carry out reasoning and generate a resource
+allocation plan. The planning results also provide sufficient
+prior knowledge for subsequent workflow input to the CLI
+module.
+Execute: The execution steps are put into practice
+through Containerized Executor, aiming to finish the creation
+of a new round of task pods combined with the analysis
+results of the MAPE-K model.
+
+7
+Knowledge Base: While not really a part of the cycle, the
+Knowledge Base stores the configuration information about
+the system and provides workflow execution status and the
+remaining resources in K8s clusters to the MAPE-K model
+running.
+In short, the KubeAdaptor needs to provide further
+analysis of the resource allocation scheme to self-optimize
+application scenarios in response to persistent workflow
+requests and sudden resource spikes.
+5
+ADAPTIVE RESOURCE ALLOCATION SCHEME
+Once Resource Manager receives a resource request of work-
+flow task from Containerized Executor, its three subcompo-
+nents immediately launch resource discovery, resource eval-
+uation, and resource allocation in turn. The entire execution
+process responds to the workflow task’s resource request
+iteratively. Next, we introduce the adaptive resource alloca-
+tion algorithm, resource discovery algorithm, and resource
+evaluation algorithm. All notations used in our algorithm
+are illustrated in Table 1. In addition, workflow execution
+states are represented as a set of state data for all tasks of
+workflow wi (1 ≤ i ≤ k) and a record of task-state data is
+defined as
+taskredis
+i,j
+= {tstart, duration, tend, cpu, mem, flag},
+1 ≤ i ≤ k, 1 ≤ j ≤ n and flag ∈ {false, true}.
+(8)
+Note that as long as KubeAdaptor starts, taskredis
+i,j
+is
+stored in Redis database through Interface Unit, and then is
+continuously updated by the Containerized Executor. Herein,
+tstart is the start time of the current task pod in K8s cluster,
+duration is similar to the definition of si,j.duration and
+represents the duration of the current task pod’s running,
+tend is the completed time of the current task in the K8s
+cluster, cpu and mem are equivalent to the definition of
+si,j.cpu and si,j.mem, and flag is a boolean variable that
+identifies the execution status of the current task pod.
+Herein, the boolean variable false indicates that the cur-
+rent task is not complete. We use Dictionary data structure
+Map < taski,j.id, taskredis
+i,j
+> to indicate state data of the
+current task, and taski,j.id is the unique identifier passed
+by task si,j of workflow wi (refers to Eq.(1)).
+Because the pod is the minimum execution unit of the
+K8s container orchestrator, coupled with KubeAdaptor’s
+non-invasive automated execution process, Resource Man-
+ager allocates resources only once throughout the requested
+task pod’s lifecycle in response to task pod’s resource re-
+quest. The users can initially set mincpu and minmem of the
+task pod in CLI module, by which this task pod ensures its
+hosted container runs smoothly.
+Algorithm 1 AdaptiveResourceAllocationAlgorithm
+Input: si,j;
+Output: allocatedcpu, allocatedmem;
+1: Initialization:
+request.cpu,
+request.mem,
+Recpu
+max,
+Remem
+max , totalResidual.cpu, totalResidual.mem ← 0;
+2: for each task pod’s resource request do
+3:
+/* Access the Redis and get the total of requested resources
+of all pods to be launched within si,j’s lifecycle */
+4:
+Get taskreq with respects to si,j of wi from Redis;
+5:
+request.cpu ← taskreq.cpu;
+6:
+request.mem ← taskreq.mem;
+7:
+Get all taskredis
+i,j
+for all workflows from Redis;
+8:
+for each task ∈ {taskredis
+i,j
+} do
+9:
+if task.tstart∈[taskreq.tstart, taskreq.tend) then
+10:
+request.cpu += task.cpu;
+11:
+request.mem += task.mem;
+12:
+end if
+13:
+end for
+14:
+/* Call the ResourceDiscoveryAlgorithm */
+15:
+ResidualMap ← ResourceDiscoveryAlgorithm;
+16:
+for each item ∈ ResidualMap do
+17:
+totalResidual.cpu += item.residual.cpu;
+18:
+totalResidual.mem += item.residual.mem;
+19:
+if item.residual.cpu >Recpu
+max then
+20:
+Recpu
+max = item.residual.cpu;
+21:
+Remem
+max = item.residual.mem;
+22:
+end if
+23:
+end for
+24:
+/* Call the ResourceEvaluationAlgorithm */
+25:
+allocatedcpu, allocatedmem ←
+26:
+ResourceEvaluationAlgorithm;
+27:
+if (allocatedcpu ≥ si,j.mincpu) and
+28:
+(allocatedmem ≥ si,j.minmem + β)
+29:
+break;
+30:
+end if then
+31: end for
+32: return allocatedcpu, allocatedmem;
+5.1
+Adaptive resource allocation algorithm
+Algorithm 1 presents an adaptive resource allocation algo-
+rithm. It initializes these parameters to be 0 in line 1 and
+takes workflow task si,j as input. Once the Containerized
+Executor sends a task pod’s resource request, the AdaptiveRe-
+sourceAllocationAlgorithm performs the following process.
+Lines 4-13 work to access the Redis database and get the
+total of requested resources of all task pods to be launched
+within si,j’s lifecycle. These task pods have resource compe-
+tition with the currently requested task pod. Subsequently,
+Algorithm 1 uses ResourceDiscoveryAlgorithm (5.2) to obtain
+the remaining resources about the K8s cluster and each
+node in the K8s cluster. Lines 16-23 traverse the remaining
+resource structure ResidualMap and accumulate to get the
+total remaining resources of all nodes across the K8s cluster.
+Meanwhile, the proposed algorithm obtains the maximal
+remaining CPU and memory resources. Herein, we assume
+that one node with the maximal remaining CPU resources
+also has the maximal remaining memory to facilitate the
+conditional comparison in ResourceEvaluationAlgorithm (pri-
+oritize CPU resource for allocation). Then, the proposed
+algorithm calls ResourceEvaluationAlgorithm to present the
+allocated resources (line 25).
+To ensure the task pod run properly in our experimental
+testbed, with the running program via Stress tool within the
+task pod in mind, we add a constant β to the minimum
+running resource for the task pod. It is because that Stress
+tool in the running program of task pod uses minmem to
+allocate and release memory resources for resource loads.
+Resource amount minmem + β as a minimum of memory
+
+8
+TABLE 1
+Major notations used in adaptive resource allocation scheme
+Notation
+Meaning
+vi
+a K8s node (VM) vi ∈ V
+si,j
+the jth task in workflow wi, 1 ≤ i ≤ k and 1 ≤ j ≤ n
+allocatedcpu
+the allocated CPU resource number through the Adaptive Resource Allocation Algorithm
+allocatedmem
+the allocated memory resource number through the Adaptive Resource Allocation Algorithm
+request.cpu
+the accumulated CPU resource number for many task requests
+request.mem
+the accumulated memory resource number for many task requests
+Recpu
+max
+the maximum remaining resource amount of CPU among K8s cluster nodes
+Remem
+max
+the maximum remaining resource amount of memory among K8s cluster nodes
+totalResidual.cpu
+the total of residual CPU resource across K8s cluster nodes
+totalResidual.mem
+the total of residual memory resource across K8s cluster nodes
+taskreq
+the current task request with respects to si,j
+taskredis
+i,j
+a record of task-state data from Redis database
+PodLister
+an interface of acquiring pod list in Informer component
+NodeLister
+an interface of acquiring node list in Informer component
+ResidualMap
+a data dictionary for storing remaining resources (CPU and memory) of each node
+nodeReq.cpu
+the accumulated CPU resource requirements for all pods on a node
+nodeReq.mem
+the accumulated memory resource requirements for all pods on a node
+allocatable.cpu
+the accumulated allocatable CPU resource across K8s cluster nodes
+allocatable.mem
+the accumulated allocatable memory resource across K8s cluster nodes
+residual.cpu
+the residual CPU resource in K8s cluster
+residual.mem
+the residual memory resource in K8s cluster
+podi
+a data struct from Podlist, which contains many key fields about container’s features
+cpucut
+the allocated CPU resource amount for task request based on Eq. (9)
+memcut
+the allocated memory resource amount for task request based on Eq. (9)
+α
+a proportional value derived from experience, α ∈ (0, 1)
+β
+a constant value derived from experience, β ≥ 20
+resource is just enough to run the task pods. Finally, the
+allocated resources returned by the proposed algorithm
+meet the conditions of minimum resource demands (line
+27).
+Algorithm 2 ResourceDiscoveryAlgorithm
+Input: PodLister, NodeLister, ResidualMap,;
+Output: ResidualMap;
+1: Initialization:
+nodeReq.cpu,
+nodeReq.mem,
+allocatable.cpu,
+allocatable.mem,
+residual.cpu,
+residual.mem ← 0;
+2: Get the PodList from PodLister through Informer;
+3: Get the NodeList from NodeLister through Informer;
+4: for node vi ∈ V do
+5:
+/*obtain the total resource requests of all pods on vi*/
+6:
+for each pod pi in PodList do
+7:
+if pi is hosted in vi then
+8:
+if podi.phase ∈ {Running, Pending} then
+9:
+nodeReq.cpu += podi.request.cpu;
+10:
+nodeReq.mem += podi.request.mem;
+11:
+end if
+12:
+end if
+13:
+end for
+14:
+/*obtain the allocatable resources on each node vi*/
+15:
+Obtain nodei from NodeList corresponding to vi.
+16:
+allocatable.cpu = nodei.allocatable.cpu;
+17:
+allocatable.mem = nodei.allocatable.mem;
+18:
+/*acquire the remaining resources on node vi*/
+19:
+residual.cpu = allocatable.cpu - nodeReq.cpu;
+20:
+residual.mem = allocatable.mem - nodeReq.mem;
+21:
+/*encapsulate Dictionary ResidualMap*/
+22:
+ResidualMap[vi.ip]={residual.cpu, residual.mem};
+23: end for
+24: return ResidualMap;
+5.2
+Resource discovery algorithm
+Algorithm 2 shows how our resource discovery algorithm
+acquires the remaining resources of the K8s cluster and
+returns the remaining resource MapResidualMap. At first
+step, this algorithm initializes related parameters to be 0 in
+line 1 and respectively get the PodList and NodeList of K8s
+cluster from PodLister and NodeLister through Informer
+component. Then the algorithm traverses all nodes in the
+K8s cluster and uses for-loop (lines 6-13) to acquire the total
+number of occupied resources for all pods with Running
+and Pending states on the current node vi. Lines 15-17
+obtain the residual CPU and memory resources on the cur-
+rent vi. Next, the algorithm encapsulates the ResidualMap
+for each vi. Once the iteration is complete for all the K8s
+cluster nodes, the algorithm returns the residual resource
+ResidualMap.
+5.3
+Resource evaluation algorithm
+Algorithm 3 elaborates the resource evaluation process
+in detail. The algorithm takes taskreq, Recpu
+max, Remem
+max ,
+totalResidual.cpu, totalResidual.mem, request.cpu and
+request.mem as input and finally return the allocated CPU
+and memory resources. As mentioned in (5.1), some task
+pods to be launched during the requested task pod’s life-
+cycle will compete for computational resources with the
+current task request taskreq, and we use a resource scaling
+method to provide resource allocation based on a propor-
+
+9
+tional value of the total remaining resources over the total
+amount of resource requests, defined as follows.
+cpucut = (taskreq.cpu) · totalResidual.cpu
+request.cpu
+,
+memcut = (taskreq.mem) · totalResidual.mem
+request.mem
+.
+(9)
+In addition, we define a resource allocation factor α for
+each node with a maximum of residual resources (CPU or
+memory). Through lots of experimental evaluations, we use
+α = 0.8, which means that the algorithm only allocates 80%
+of the remaining resources in response to insufficient resid-
+ual resource scenario on the current node while ensuring
+20% residual resources for its other loads.
+Algorithm 3 ResourceEvaluationAlgorithm
+Input: taskreq, Recpu
+max, Remem
+max , totalResidual.cpu,
+totalResidual.mem; request.cpu, request.mem;
+Output: allocated.cpu, allocated.mem;
+1: Get cpucut and memcut through Eq. (9);
+2: define
+conditions
+request.cpu<totalResidual.cpu
+as
+A1,
+request.mem<totalResidual.mem
+as
+A2,
+taskreq.cpu<Recpu
+max as B1, taskreq.mem<Remem
+max
+as
+B2, cpucut<Recpu
+max as C1, and memcut<Remem
+max as C2;
+3: define the symbol ¬ as the negation of a condition and
+the symbol ∧ as the logical and.
+4: /* (1) The remaining resources are sufficient */
+5: if A1 ∧ A2 then
+6:
+if B1 ∧ B2 then
+7:
+allocated.cpu = taskreq.cpu
+8:
+allocated.mem = taskreq.mem
+9:
+else
+10:
+if ¬B1 ∧ B2 then
+11:
+allocated.cpu = Recpu
+max · α
+12:
+allocated.mem = taskreq.mem
+13:
+else
+14:
+if B1 ∧ ¬B2 then
+15:
+allocated.cpu = taskreq.cpu
+16:
+allocated.mem = Remem
+max · α
+17:
+else
+18:
+allocated.cpu = Recpu
+max · α
+19:
+allocated.mem = Remem
+max · α
+20:
+end if
+21:
+end if
+22:
+end if
+23: end if
+24: /* (2) The remaining cpu resource is unsufficient */
+25: if ¬A1 ∧ A2 then
+26:
+if C1 ∧ B2 then
+27:
+allocated.cpu = cpucut
+28:
+allocated.mem = taskreq.mem
+29:
+else
+30:
+if ¬C1 ∧ B2 then
+31:
+allocated.cpu = Recpu
+max · α
+32:
+allocated.mem = taskreq.mem
+33:
+else
+34:
+if C1 ∧ ¬B2 then
+35:
+allocated.cpu = cpucut
+36:
+allocated.mem = Remem
+max · α
+37:
+else
+38:
+allocated.cpu = Recpu
+max · α
+39:
+allocated.mem = Remem
+max · α
+40:
+end if
+41:
+end if
+42:
+end if
+43: end if
+44: /* (3) The remaining memory resource is unsufficient */
+45: if A1 ∧ ¬A2 then
+46:
+if B1 ∧ C2 then
+47:
+allocated.cpu = taskreq.cpu
+48:
+allocated.mem = memcut
+49:
+else
+50:
+if ¬B1 ∧ C2 then
+51:
+allocated.cpu = Recpu
+max · α
+52:
+allocated.mem = memcut
+53:
+else
+54:
+if B1 ∧ ¬C2 then
+55:
+allocated.cpu = taskreq.cpu
+56:
+allocated.mem = Remem
+max · α
+57:
+else
+58:
+allocated.cpu = Recpu
+max · α
+59:
+allocated.mem = Remem
+max · α
+60:
+end if
+61:
+end if
+62:
+end if
+63: end if
+64: /* (4) Both residual resources are unsufficient */
+65: if ¬A1 ∧ ¬A2 then
+66:
+allocated.cpu = cpucut
+67:
+allocated.mem = memcut
+68: end if
+69: return allocated.cpu, allocated.mem;
+Algorithm 3 first uses resource scaling to obtain allocated
+CPU and memory resources by Eq. (9) and defines six
+comparative conditions A1, A2, B1, B2, C1 and C2 (lines
+1-2). The symbol ¬ denotes the negation of the condition
+and the symbol ∧ denotes the logical and (line 3). Then
+the algorithm implements four resource allocation scenarios
+according to comparative conditions between accumulated
+resource requests (concurrent scenario) within the current
+task lifecycle and the total residual resources.
+Sufficient residual resources. When the total residual
+resources across the K8s cluster are abundant for concurrent
+tasks within the current task lifecycle, we only think about
+B1 and B2. When the CPU and memory resource requests of
+the current taskreq are smaller than the maximum remain-
+ing resources of a node (meets B1 and B2), the algorithm
+allocates resources in the light of the current task request
+taskreq (lines 6-8). If the maximum remaining CPU resource
+on the cluster node fails to suffice for the current task request
+taskreq, the algorithm allocates Recpu
+max · α of the maximum
+remaining CPU resource on cluster node (lines 10-12). Con-
+versely, so is memory (lines 14-16). When neither of the two
+remaining resources on cluster node (CPU and memory) can
+satisfy taskreq, both types of allocated resources scale down
+by multiplying α (lines 17-19).
+Insufficient residual CPU resource. When the total
+residual CPU resource across the K8s cluster cannot satisfy
+the total resource demand of concurrent tasks, conditions
+C1 and B2 are considered. The algorithm acquires the cpucut
+
+10
+through the resource scaling method (Eq. (9)). In case of con-
+ditions C1 and B2, we allocate resources according to cpucut
+and taskreq.mem (lines 26-28). When the maximum CPU re-
+maining resources of a node fail to accommodate cpucut, the
+algorithm adopts Recpu
+max · α as the allocated CPU resource.
+Due to sufficient memory capacities, the algorithm suffices
+for the current task memory request taskreq.mem (lines 30-
+32). In case of conditions C1 ∧ ¬B2, the algorithm allocates
+cpucut CPU resource and Remem
+max · α memory resource,
+which is due to that the current task memory request is
+greater than the maximum residual memory resource on
+cluster node (lines 34-36). Instead, the algorithm allocates
+resources (CPU and memory) according to the α scale factor
+of the largest node’s remaining resources (lines 37-39).
+Insufficient residual memory resource. When the total
+residual memory resource across the K8s cluster cannot
+satisfy the total resource demand of concurrent tasks, condi-
+tions B1 and C2 are considered. The algorithm acquires the
+memcut through the resource scaling method (Eq. (9)). The
+operations under conditions B1 ∧ C2, ¬B1 ∧ C2, B1 ∧ ¬C2
+and ¬B1 ∧ ¬C2 are similar to the above, except that here
+we are talking about memory resource (lines 45-63).
+Insufficient residual CPU and memory resources. In
+the case of ¬A1 ∧ ¬A2, meaning that the total remaining
+CPU and memory resources across the K8s cluster fail
+to suffice for the CPU and memory resource requests of
+concurrent tasks, the algorithm allocates CPU and memory
+resources according to cpucut and memcut obtained by
+resource scaling method (lines 65-67). Finally, ResourceEvalu-
+ationAlgorithm returns allocated resources allocated.cpu and
+allocated.mem.
+6
+EXPERIMENTAL EVALUATION
+In the following, we evaluate the proposed ARAS for differ-
+ent evaluation metrics and discuss the benefits of the pro-
+posed ARAS under three distinct arrival patterns compared
+with the baseline.
+6.1
+Experimental setup and design
+For the evaluation, we apply a setting employed in our
+former work [21] and make adaptations for the proposed
+ARAS within KubeAdaptor discussed here. In this subsec-
+tion, we briefly introduce experimental scenarios, work-
+flow examples, workflow instantiation, workflow arrival
+patterns, evaluation metrics, and baseline algorithm.
+6.1.1
+Experimental scenarios
+The K8s cluster used in our experiments consists of one
+Master node and six nodes. Each node equips with an 8-core
+AMD EPYC 7742 2.2GHz CPU and 16GB of RAM, running
+Ubuntu 20.4 and K8s v1.19.6 and Docker version 18.09.6.
+The Redis database v5.0.7 is installed on the Master node.
+Workflow Injector Module and Containerized Workflow Builder
+are containerized and deployed into the K8s cluster through
+Service 11 and Deployment 12. We explore the performances of
+the proposed ARAS and baseline by running four scientific
+workflows on the K8s cluster.
+11. https://kubernetes.io/docs/concepts/
+12. https://kubernetes.io/docs/concepts/workloads/
+6.1.2
+Workflow examples
+To verify the adaptations of our proposed ARAS within
+KubeAdaptor, four scientific workflows, such as Mon-
+tage (astronomy), Epigenomics (genome sequence), Cyber-
+Shake (earthquake science), and LIGO Inspiral (gravita-
+tional physics), are used to run on K8s cluster in a con-
+tainerized manner [3]. We make a few tweaks to the work-
+flow structure and add virtual entrance and exit nodes of
+workflows to form the workflow structure with the DAG
+diagram. As for each type of scientific workflow, we uni-
+formly adopt a small-scale workflow (about 20 tasks) in our
+experiments, as shown in Fig. 4, derived from the Pegasus
+Workflow repository [37]. Structurally, four types of work-
+flows cover all the structural features regarding composition
+and components (in-tree, out-tree, fork-join, and pipeline)
+that serve to illustrate the universality and complexity of
+workflows. Herein, we only consider the topologies of four
+scientific workflows and do not focus on the real-world
+data processing of the tasks, which does not affect verifying
+the adaptability of our ARAS. For ease of performance
+comparisons among resource allocation solutions, we as-
+sume that four classes of scientific workflows consist of the
+same tasks. Each node of workflow DAGs uses resource
+load (CPU and memory utilization) and service runtime to
+simulate workflow tasks in the experiments. Note that the
+KubeAdaptor schedules workflow tasks topologically in a
+top-down fashion according to task dependencies.
+6.1.3
+Workflow instantiation
+As for resource load in workflow tasks, we employ sev-
+eral parameters together with Stress to work on simulating
+scientific workflow tasks. In each task program, we use
+the Stress 13 tool to set several CPU forks, a memory of
+1000Mi (is equal to memmin of Eq. (1)), and random dura-
+tion (user’s definition ahead of time in Eq. (1)). CPU forking
+and memory allocation operations in the task pod last twice
+as long as duraion. The total duration of each task pod is
+random and falls between 10s and 20s. Then we pack the
+Python application with Stress program into a task Image
+file through Docker Engine 14, store the task Image file in
+local Harbor 15 or remote Docker Hub repository 16. We can
+import container parameters (refer to Eq. (1)) defined in the
+ConfigMap file of in Workflow Injection Module into the task
+container hosted in the task pod. For resource setting within
+task pod, we uniformly set the resource requests and limits
+to 2000 Milli cores (i.e., 2000m) CPU and 4000Mi memory.
+Note that the requests field has the same parameter as the
+limits field, which ensures that this task pod has the highest
+priority, namely Guaranteed [38].
+6.1.4
+Workflow arrival patterns
+We make use of three distinct workflow request arrival
+patterns:
+Constant Arrival Scenario: In this scenario, workflow
+requests arrive in a constant manner. Workflow Injector Mod-
+uler together with CLI sends 5 workflow requests simulta-
+13. https://linux.die.net/man/1/stress
+14. https://github.com/IsaacKlop/task-emulator
+15. https://goharbor.io/
+16. https://docs.docker.com/docker-hub/repos/
+
+11
+T3
+T4
+T5
+T6
+T1
+T12
+T13
+T14
+T15
+T7
+T8
+T9
+T10
+T2
+T16
+T17
+T18
+T19
+T11
+T20
+T0
+T21
+T3
+T4
+T5
+T6
+T1
+T12
+T13
+T14
+T15
+T7
+T8
+T9
+T10
+T2
+T16
+T17
+T18
+T19
+T11
+T20
+T0
+T21
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T17
+T18
+T19
+T20
+T0
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T17
+T18
+T19
+T20
+T0
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T17
+T18
+T19
+T0
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T17
+T18
+T19
+T0
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T1
+T2
+T3
+T4
+T6
+T7
+T8
+T9
+T22
+T12
+T13
+T14
+T15
+T17
+T18
+T19
+T20
+T5
+T10
+T16
+T21
+T11
+T0
+T1
+T2
+T3
+T4
+T6
+T7
+T8
+T9
+T22
+T12
+T13
+T14
+T15
+T17
+T18
+T19
+T20
+T5
+T10
+T16
+T21
+T11
+T0
+(a) Montage
+(b) Epigenomics
+(c) CyberShake
+(d) LIGO
+T3
+T4
+T5
+T6
+T1
+T12
+T13
+T14
+T15
+T7
+T8
+T9
+T10
+T2
+T16
+T17
+T18
+T19
+T11
+T20
+T0
+T21
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T17
+T18
+T19
+T20
+T0
+T1
+T2
+T3
+T4
+T5
+T6
+T7
+T8
+T17
+T18
+T19
+T0
+T9
+T10
+T11
+T12
+T13
+T14
+T15
+T16
+T1
+T2
+T3
+T4
+T6
+T7
+T8
+T9
+T22
+T12
+T13
+T14
+T15
+T17
+T18
+T19
+T20
+T5
+T10
+T16
+T21
+T11
+T0
+(a) Montage
+(b) Epigenomics
+(c) CyberShake
+(d) LIGO
+Fig. 4. The topology diagram of four scientific workflow applications.
+neously to the Containerized Workflow Builder every 300 sec-
+onds, i.e., y = 5. Send six times for a total of 30 workflows.
+A graphical depiction of this arrival curve is depicted in
+Fig. 5(a).
+Linear Arrival Scenario: In this scenario, the workflow
+requests are injected into Containerized Workflow Builder in
+a linear rising function, i.e., y = k ∗ x + d, where y is the
+amount of concurrent workflow request and d is the initial
+value 2. Concurrent workflow requests increase by k = 2
+every 300 seconds. This linear arrival curve is depicted in
+Fig. 5(b). Send five times for a total of 30 workflows.
+Pyramid Arrival Scenario: In this scenario, workflow
+requests are sent to Containerized Workflow Builder in line
+with a pyramid-like function. We start with a small number
+of concurrent workflow requests (is equal to 2), till it grows
+to a randomly selected large number (is equal to 6 for
+each type of workflow), which can be seen in Fig. 5(c).
+Concurrent workflow requests grow every 300 seconds by
+2 until the peak is reached. Once the peak reaches, we
+immediately reduce this number to the small initial value
+in the same manner and repeat this process until the total
+number of workflow requests is reached (herein, 34).
+The deployment of these three scenarios aims to max-
+imize coverage of the ever-changing resource needs and
+sudden peaks of workflow requests in a production envi-
+ronment. Even if there is some predictability in the Constant
+and Linear Arrival scenarios, the Pyramid function follows
+an unpredictable arrival pattern.
+6.1.5
+Evaluation metrics
+To evaluate our ARAS, we conduct each arrival pattern
+three times and analyze the results against the following
+quantitative metrics:
+Total Duration of All Workflows (in Minutes): This
+metric is the average total duration of all injected work-
+flows, i.e., the elapsed time from the arrival of the first
+workflow request to the moment when the last workflow
+request is complete.
+Average Workflow Duration (in Minutes): This metric
+reflects the average execution time of individual workflow,
+which is the time that each workflow takes from the start of
+the first task to the end of the last.
+Resource Usage: Resource usage contains CPU and
+memory resource utilization, reflecting the average resource
+utilization throughout the total duration of all injected
+workflows across the K8s cluster. The greater the resource
+utilization, the closer to our optimization goal. The resource
+usage comparison covering four types of scientific work-
+flows with the baseline algorithm further verifies the better
+performance of our ARAS solution.
+6.1.6
+Baseline
+In experiments, we used our recent resource allocation
+strategy [21] as a baseline method, which does not take
+into account the potential future task requests throughout
+the current task’s lifecycle. It means that the resource al-
+location strategy in the baseline follows the First Come
+First Serve (FCFS) and relies on the adequacy of residual
+resources on cluster nodes. If enough, the resource allocation
+is complete. Otherwise, wait for other task pods to complete
+and release resources to meet the resource reallocation for
+the current task request.
+6.2
+Results and analysis
+To fully evaluate KubeAdaptor together with our ARAS, we
+present a general evaluation and the evaluation of resource
+allocation failure, and discuss the evaluation results. In
+order to minimize external influences, our K8s cluster has
+no other application load, and we execute each evaluation
+three times at different times of one day.
+6.2.1
+General evaluation
+In the following, we use the KubeAdaptor with our ARAS
+and the baseline to run four scientific workflows against
+three distinct workflow arrival patterns three times and
+compare our ARAS with the baseline on experimental re-
+sults. We calculate the mean value and the standard devia-
+tion δ for all metrics.
+Table 2 presents the resulting mean values and the
+standard deviation from the conducted evaluation runs.
+In general, the observed standard deviation is low and
+therefore indicates a low dispersion in the results of the
+different evaluations. As presented in Table 2, ”Adaptive”
+
+12
+TABLE 2
+Evaluation results
+Workflow
+Metrics
+Constant Arrival
+Linear Arrival
+Pyramid Arrival
+Adaptive
+Baseline
+Adaptive
+Baseline
+Adaptive
+Baseline
+Number of Workflow Rquests
+30
+30
+34
+Types
+Interval between two Requests Bursts (in
+Seconds)
+300
+300
+300
+Montage
+Total Duration of All Workflows in Minutes
+33.18
+36.79
+26.95
+36.45
+49.31
+54.69
+(Standard Deviation)
+(δ = 0.21)
+(δ = 2.26)
+(δ = 0.38)
+(δ = 6.31)
+(δ = 2.46)
+(δ = 1.74)
+Average Workflow Duration in Minutes
+5.74
+7.80
+5.41
+11.33
+7.22
+11.73
+(Standard Deviation)
+(δ = 0.49)
+(δ = 0.36)
+(δ = 0.26)
+(δ = 4.28)
+(δ = 1.36)
+(δ = 0.88)
+CPU resource Usage
+0.28
+0.27
+0.35
+0.31
+0.26
+0.20
+(Standard Deviation)
+(δ = 0.00)
+(δ = 0.02)
+(δ = 0.01)
+(δ = 0.07)
+(δ = 0.03)
+(δ = 0.01)
+Memory resource Usage
+0.28
+0.27
+0.35
+0.31
+0.26
+0.20
+(Standard Deviation)
+(δ = 0.00)
+(δ = 0.13)
+(δ = 0.01)
+(δ = 0.07)
+(δ = 0.03)
+(δ = 0.01)
+Epigenomics
+Total Duration of All Workflows in Minutes
+30.55
+39.06
+34.3
+43.66
+51.42
+62.12
+(Standard Deviation)
+(δ = 0.19)
+(δ = 1.84)
+(δ = 7.29)
+(δ = 4.37)
+(δ = 4.28)
+(δ = 4.32)
+Average Workflow Duration in Minutes
+4.24
+9.35
+9.81
+16.53
+9.65
+19.41
+(Standard Deviation)
+(δ = 0.05)
+(δ = 1.56)
+(δ = 5.11)
+(δ = 4.41)
+(δ = 3.33)
+(δ = 6.04)
+CPU resource Usage
+0.34
+0.27
+0.32
+0.25
+0.21
+0.20
+(Standard Deviation)
+(δ = 0.02)
+(δ = 0.01)
+(δ = 0.06)
+(δ = 0.00)
+(δ = 0.00)
+(δ = 0.00)
+Memory resource Usage
+0.34
+0.27
+0.32
+0.25
+0.21
+0.20
+(Standard Deviation)
+(δ = 0.02)
+(δ = 0.01)
+(δ = 0.06)
+(δ = 0.00)
+(δ = 0.01)
+(δ = 0.01)
+CyberShake
+Total Duration of All Workflows in Minutes
+38.30
+50.29
+34.06
+49.46
+46.76
+66.41
+(Standard Deviation)
+(δ = 5.77)
+(δ = 5.29)
+(δ = 6.16)
+(δ = 1.18)
+(δ = 4.02)
+(δ = 6.56)
+Average Workflow Duration in Minutes
+9.19
+17.29
+9.41
+20.61
+4.94
+19.47
+(Standard Deviation)
+(δ = 3.72)
+(δ = 2.89)
+(δ = 4.27)
+(δ = 0.86)
+(δ = 2.07)
+(δ = 6.50)
+CPU resource Usage
+0.26
+0.24
+0.27
+0.24
+0.22
+0.19
+(Standard Deviation)
+(δ = 0.03)
+(δ = 0.02)
+(δ = 0.04)
+(δ = 0.01)
+(δ = 0.03)
+(δ = 0.01)
+Memory resource Usage
+0.26
+0.24
+0.27
+0.23
+0.22
+0.19
+(Standard Deviation)
+(δ = 0.03)
+(δ = 0.02)
+(δ = 0.04)
+(δ = 0.01)
+(δ = 0.03)
+(δ = 0.01)
+LIGO
+Total Duration of All Workflows in Minutes
+30.82
+52.17
+44.02
+53.87
+45.26
+63.56
+(Standard Deviation)
+(δ = 0.38)
+(δ = 3.99)
+(δ = 10.9)
+(δ = 4.20)
+(δ = 0.52)
+(δ = 1.60)
+Average Workflow Duration in Minutes
+4.26
+21.15
+16.21
+28.05
+4.20
+14.07
+(Standard Deviation)
+(δ = 0.09)
+(δ = 0.44)
+(δ = 7.68)
+(δ = 7.88)
+(δ = 0.15)
+(δ = 1.33)
+CPU resource Usage
+0.40
+0.24
+0.28
+0.23
+0.31
+0.23
+(Standard Deviation)
+(δ = 0.00)
+(δ = 0.02)
+(δ = 0.08)
+(δ = 0.02)
+(δ = 0.01)
+(δ = 0.00)
+Memory resource Usage
+0.40
+0.24
+0.28
+0.23
+0.31
+0.23
+(Standard Deviation)
+(δ = 0.00)
+(δ = 0.02)
+(δ = 0.08)
+(δ = 0.02)
+(δ = 0.01)
+(δ = 0.00)
+denotes our ARAS, while ”Baseline” marks the application
+of the baseline algorithm (mentioned in 6.1.6). The interval
+between two workflow request bursts is set to 300 seconds
+for three arrival patterns, and the amount of injected work-
+flows for three arrival patterns is set to 30, 30, and 34,
+respectively.
+Generally, our ARAS is superior to the baseline algo-
+rithm on each observation metric against four different
+workflow types under distinct workflow arrival patterns.
+In addition, The CPU and memory resources set in the task
+pod are constant, the allocatable cluster resources are fixed,
+and the resource scaling method scales down resources
+according to Eq. (9). So no matter in each arrival pattern and
+each resource allocation algorithm, the utilization rate of
+CPU and memory resources are the same, and both resource
+usage curves in each workflow arrival pattern are similar. In
+the following, we elaborate on the evaluation metrics of each
+workflow arrival pattern in the light of workflow types.
+From Fig. 5 to Fig. 8 illustrate the presentation of the
+average evaluation results by depicting the arrival pat-
+terns (Workflow Requests) over time and the number of
+used computational resources (CPU and memory) until all
+workflow requests have been served. Note that the used
+resource curve in each workflow arrival pattern usually
+ends later than the workflow request curve. It can be traced
+to the fact that each workflow has a deadline in the future,
+and some workflows are still waiting in queue for execution.
+Montage: In our experimental setup, a small-scale Mon-
+tage workflow consists of 21 tasks (refers to Fig. 4(a)).
+Compared with the baseline, as for the total duration of
+all workflows in Table 2, our ARAS leads to time savings
+of 9.8% for the constant arrival pattern and time savings of
+26.06% for the linear arrival pattern, while in the pyramid
+arrival pattern, time savings amounts to 9.8%. Similarly, as
+for average workflow duration, our ARAS, in comparison to
+the baseline, gains a time saving of 26.4%, time savings of
+52.3%, and time savings of 38.5% for three different work-
+flow arrival patterns from left to right, respectively. Fig. 5
+broadly reflects the consistency of the above data with the
+total duration of all injected workflows, even with a set of
+
+13
+0
+10
+20
+30
+40
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+5
+10
+15
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+constant arrival pattern
+0
+10
+20
+30
+40
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+5
+10
+15
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+constant arrival pattern
+(a) Constant Arrival Pattern
+0
+10
+20
+30
+40
+45
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+linear arrival pattern
+0
+10
+20
+30
+40
+45
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+linear arrival pattern
+(b) Linear Arrival Pattern
+0
+10
+20
+30
+40
+50
+60
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+pyramid arrival pattern
+0
+10
+20
+30
+40
+50
+60
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+pyramid arrival pattern
+(c) Pyramid Arrival Pattern
+Fig. 5. The CPU and memory resource usage rate under three distinct arrival patterns for Montage workflows.
+evaluation data. Our ARAS achieves better performances in
+total workflow duration and average workflow duration in
+linear arrival patterns. It can be deduced that the concurrent
+degree of received workflow requests is directly related to
+the total duration of all injected workflows and the average
+duration of a single workflow. The higher the concurrent
+degree of received workflow requests, the more workflow
+tasks are executed per unit time, so the shorter the total
+duration of all injected workflows and the average duration
+of individual workflow.
+Regarding the CPU and memory resource usage in Fig. 5,
+our ARAS outperforms the baseline for each arrival pattern.
+Herein, the linear arrival pattern features a maximum value
+of 35% for our ARAS, 4% higher than the baseline algo-
+rithm. Our ARAS outperforms the baseline algorithm by
+1% and 6%, respectively, in the other two patterns. It can
+be traced back to the fact that over time the linear arrival
+pattern requests more task pods to be performed in parallel
+in response to more and more workflow requests and gains
+a maximum resource usage rate.
+Looking at the resource usage curves (CPU and memory)
+of three workflow arrival patterns in Fig. 5, the resource
+usage peak of our ARAS is higher than that of the baseline
+algorithm for most of the time. It can be further observed
+that the peak of the resource usage curve is consistent with
+the centralized arrival of workflow requests. It is because
+our ARAS can use a resource scaling strategy to adjust the
+resource limits of potential future task requests within the
+current task’s lifecycle. This scheme launches task pods as
+many as possible on the premise of the smooth operation
+of task pods, thus speeding up the execution efficiency
+of workflows. However, the baseline algorithm depends
+on the adequacy of residual resources on cluster nodes.
+In high concurrency scenarios, the insufficient remaining
+resources of nodes will make the baseline algorithm lead
+to endless waiting and much time-wasting and prolong the
+total duration of workflows and the average duration of a
+single workflow.
+Epigenomics: We adopt a small-scale Epigenomics
+workflow with 20 tasks in experimental evaluations. As
+can be seen from Fig. 4(b), the topology of Epigenomics
+workflows is mostly pipeline structure. As for the total
+duration of all workflows, our ARAS obtains time savings
+of 21.8% for the constant arrival pattern, time savings of
+21.4% for the linear arrival pattern, and time savings of
+17.2% for the pyramid arrival pattern compared with the
+baseline. As for average workflow duration, our ARAS, in
+comparison to the baseline, gains time savings of 54.65%,
+time savings of 40.65%, and time savings of 50.28% for three
+arrival patterns from left to right, respectively. Note that
+the Epigenomics workflow is substantially more significant
+in performance improvement than the Montage workflow
+in terms of average total workflow duration and average
+duration of individual workflow for three arrival patterns.
+Because the pipeline topology in the Epigenomics workflow
+is better suited for high concurrency scenarios, our ARAS
+scheme saves more time than the baseline in response to
+continuous workflow requests.
+Regarding the resource usage in Fig. 6, the constant
+arrival pattern features a maximum value of 34% for our
+ARAS, 7% higher than the baseline. The linear arrival pat-
+tern features a value of 32% for our ARAS, which is also 7%
+higher than the baseline. The higher resource utilization of
+these two patterns can be attributed to the fact that 30 work-
+flows were injected in the first 25 minutes, totaling more
+than 600 tasks. The higher density of workflow requests
+results in higher CPU and memory resource utilization. In
+addition, the resource scaling method enables our ARAS
+to adjust the resource limits of the task pods in time and
+cope with the continuous workflow requests on the premise
+
+14
+0
+10
+20
+30
+40
+45
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+5
+10
+15
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+constant arrival pattern
+0
+10
+20
+30
+40
+45
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+5
+10
+15
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+constant arrival pattern
+(a) Constant Arrival Pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+linear arrival pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+linear arrival pattern
+(b) Linear Arrival Pattern
+0
+10
+20
+30
+40
+50
+60
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+pyramid arrival pattern
+0
+10
+20
+30
+40
+50
+60
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+pyramid arrival pattern
+(c) Pyramid Arrival Pattern
+Fig. 6. The CPU and memory resource usage rate under three distinct arrival patterns for Epigenomics workflows.
+of the normal execution of workflow tasks. It also shows
+that the peak time of resource usage in our ARAS is longer
+than that of the baseline. The baseline algorithm waits for
+resource release in response to resource shortage on cluster
+nodes, so it consumes too much time and results in a longer
+total workflow duration and average duration of a single
+workflow.
+CyberShake: A small-scale CyberShake workflow in our
+experiments comprises 22 tasks (refers to Fig. 4(c)). Our
+ARAS, in comparison to the baseline, leads to time savings
+of 23.8% (for the constant arrival pattern), time savings
+of 31.1% (for the linear arrival pattern), and time savings
+of 29.6% (for the pyramid arrival pattern) for the total
+duration of all workflows. Similarly, for average workflow
+duration, our ARAS, in comparison to the baseline, gains
+time savings of 46.85%, time savings of 54.34%, and time
+savings of 74.63% for three arrival patterns from left to right,
+respectively.
+Due to the topology structure of the CyberShake work-
+flow with smaller depth and greater width, the CyberShke
+workflow features a higher degree of inherent parallelism,
+which is easier to take advantage of our ARAS in response to
+continuous workflow request arrivals. Compared with the
+baseline algorithm, the ARAS has prominent performance
+advantages on metrics of total workflow duration and dura-
+tion of a single workflow. As for CPU and memory resource
+usage, our ARAS obtains 26%, 27%, and 22% for three
+distinct arrival patterns, respectively, and slightly higher
+than the baseline. Combined with the resource utilization
+curve in Fig. 7, it can be observed that our ARAS benefiting
+from the resource scaling method outperforms the baseline
+in all performance metrics under three different workflow
+arrival patterns.
+LIGO: A small-scale LIGO workflow in our experiments
+consists of 23 tasks (refers to Fig. 4(d)). Compared with
+the baseline, our ARAS gains time savings of 40.92% (for
+the constant arrival pattern), time savings of 18.28% (for
+the linear arrival pattern), and time savings of 28.79% (for
+the pyramid arrival pattern) for the total duration of all
+workflows. Similarly, for average workflow duration, our
+ARAS, in comparison to the baseline, gains time savings
+of 79.86%, time savings of 42.21%, and time savings of
+70.15% for three arrival patterns from left to right, respec-
+tively. With unique concurrent topology, LIGO workflows,
+like Epigenomics and CyberShake workflows, enable our
+ARAS to perform better in the total workflow duration
+and individual workflow duration metrics than the baseline
+algorithm under three different arrival patterns.
+As for resource usage in Fig. 8, our ARAS obtained
+40% for the constant arrival pattern, 28% for linear arrival
+pattern and 31% for pyramid arrival pattern, respectively,
+much higher than the baseline algorithm. In combination
+with the resource utilization curve trend, resource scaling
+strategy and workflow’s unique concurrency topology once
+again help our ARAS outperform the baseline under three
+different workflow arrival patterns.
+6.2.2
+Evaluation of resource allocation failure
+In
+this
+evaluation,
+we
+analyze
+the
+behavior
+of
+the
+KubeAdaptor in a failure situation of resource allocation.
+This situation means that our ARAS allocates resource
+quotas less than minmem + β through the resource scaling
+method against a high-concurrency scenario. So the task
+pods cannot smoothly execute and turn to OOMKilled
+status due to insufficient memory resources. Accordingly,
+the OOMKilled task pods make the workflow running get
+stuck. The source code of evaluation of resource allocation
+failture is available at 17.
+In the following, we investigate how KuberAdaptor re-
+sponds to OOMKilled task pods, reallocates resources to ex-
+17. https://github.com/CloudControlSystems/OOM-Test
+
+15
+0
+10
+20
+30
+40
+45
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+5
+10
+15
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+constant arrival pattern
+0
+10
+20
+30
+40
+45
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+5
+10
+15
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+constant arrival pattern
+(a) Constant Arrival Pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+linear arrival pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+linear arrival pattern
+(b) Linear Arrival Pattern
+0
+10
+20
+30
+40
+50
+60
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+pyramid arrival pattern
+0
+10
+20
+30
+40
+50
+60
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+pyramid arrival pattern
+(c) Pyramid Arrival Pattern
+Fig. 7. The CPU and memory resource usage rate under three distinct arrival patterns for CyberShake workflows.
+ecute task pods, and resumes workflow execution under our
+ARAS. For this evaluation, we inject 10 Montage workflows
+into our K8s cluster (mentioned in 6.1.1) at a time under the
+constant arrival pattern. We fine-tune mincpu and minmem
+to be less than the amount of memory required by the Stress
+tool in the task pod. Subsequently, our ARAS tries to reduce
+the allocated resource quota by the resource scaling method
+in response to continuous workflow requests. When the
+allocated resource is less than minmem+β, OOMKilled task
+pods will appear due to running resource shortage.
+Fig. 9 depicts the results of this evaluation. In Fig. 9
+the first annotation marker, labeled OOMKilled, signalizes
+when the current task pod encounters the OOM (Out of
+Memory) event, and the other annotation marker, labeled
+Reallocation, signalizes when the current task pod is re-
+generated by using the reallocated computational resources.
+As can be seen in Fig. 9, at the beginning (second 0), our
+ARAS uses the resource scaling method to allocate CPU of
+1048 Milli cores and memory of 2009Mi. In this evalua-
+tion, the minimum memory for a task pod to run, i.e., the
+amount of memory operated by the Stress tool in the task
+pod is set to 2000Mi. Herein, we only focus on memory
+resources because memory resources are incompressible
+resources, and insufficient memory resources will trigger the
+task pod OOMKilled, while CPU resources as compressible
+resources do not. Once the allocated memory resource fails
+to reach minmem + β (i.e., 2000Mi + 20Mi), the current
+task pod turns to OOMKilled at 66s. Meanwhile, the work-
+flow with the current OOMKilled task pod also terminates
+execution. KubeAdaptor can capture the OOMKilled task
+pod and delete the task pod at 66s. In our experimental
+evaluation, up to 210 task pods (10 Montage workflows)
+possess frequent created and deleted operations, leading
+to operation delay of deleting OOMKilled task pod. At
+97s, KubeAdaptor triggers the regeneration of the current
+task pod, reallocates computational resources, and launches
+the task pod. Since the second allocation of resources is
+sufficient for the smooth execution of the task pod (1849m
+CPU and 3560Mi memory), the task pod is completed at
+181s. At 258s, KubeAdaptor deletes the completed task pod.
+KubeAdaptor equipped with our ARAS in this paper
+can watch OOMKilled events, delete these OOMKilled task
+pods, reallocate computational resources, and regenerate
+these OOMKilled task pods, ensuring continuous execution
+of workflows. In production practice, the users inevitably
+misestimate the resource quota of the main program inside
+workflow tasks, resulting in a large number of OOMKilled
+task pods and termination of workflow execution. These
+countermeasures ensure continuous executions of work-
+flows and keep the KubeAdaptor stable and robust. It also
+reflects the self-healing and self-configuration abilities of the
+KubeAdaptor (mentioned in 4.3).
+6.2.3
+Concluding discussion
+Finally, it can be observed that the KubeAdaptor with our
+ARAS always achieves better results regarding each met-
+ric (Sections 6.1.5). From Montage workflows to LIGO work-
+flows, our ARAS outperforms the baseline against different
+metrics under three distinct workflow arrival patterns.
+Most of the time savings from the total workflow du-
+ration and average duration of individual workflow result
+from the fact that the resource scaling method enables our
+ARAS to maximize resource utilization on cluster nodes
+according to our optimized functions while ensuring the
+smooth running of workflow pods. In addition, the work-
+flow topology with concurrent characteristics also plays a
+positive role.
+Concerning resource allocation failure and workflow
+recovery after termination, we have shown in Section 6.2.2
+that the KubeAdaptor has abilities to watch the state
+
+16
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+5
+10
+15
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+constant arrival pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+5
+10
+15
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+constant arrival pattern
+(a) Constant Arrival Pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+linear arrival pattern
+0
+10
+20
+30
+40
+50
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+12
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+linear arrival pattern
+(b) Linear Arrival Pattern
+0
+10
+20
+30
+40
+50
+60
+65
+Time (Minutes)
+0
+20
+40
+60
+#CPU (Cores)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable cpu
+used cpu in Adaptive
+used cpu in baseline
+pyramid arrival pattern
+0
+10
+20
+30
+40
+50
+60
+65
+Time (Minutes)
+0
+20
+40
+60
+80
+100
+120
+#Memory (Gi)
+0
+2
+4
+6
+8
+10
+Workflow Requests
+allocatable memory
+used memory in Adaptive
+used memory in baseline
+pyramid arrival pattern
+(c) Pyramid Arrival Pattern
+Fig. 8. The CPU and memory resource usage rate under three distinct arrival patterns for LIGO workflows.
+0
+50
+100
+150
+200
+250
+300
+350
+400
+0
+1000
+2000
+3000
+4000
+5000
+6000
+#CPU (Milli Cores)
+OOMKilled
+Reallocation
+allocated cpu of OOMKilled task pod
+reallocated cpu of this task pod
+0
+50
+100
+150
+200
+250
+300
+350
+400
+Time (Seconds)
+0
+2000
+4000
+6000
+8000
+#Memory (Mi)
+OOMKilled
+Reallocation
+allocated memory of OOMKilled task pod
+reallocated memory of this task pod
+Minimum memory for the task pod to run
+Fig. 9. Evaluation results of resource allocation failure. The first vertical
+blue line labeled OOMKilled indicates that this task pod encounters
+OOMKilled due to insufficient allocated memory resources. Another ver-
+tical blue line labeled Reallocation indicates that the task pod previously
+OOMKilled is recreated due to sufficient allocated memory resources.
+changes of task pods in real-time, delete the OOMKilled
+task pods, and reallocate computational resources for the
+task pod, followed by the re-creation of this OOMKilled
+task pod and recover of workflow executing.
+7
+CONCLUSION
+In this paper, we propose an ARAS for our tailored work-
+flow management engine. With the novel architecture of
+KubeAdaptor and the integration between KubeAdaptor
+and K8s, our ARAS enables the KubeAdaptor to maximize
+resource utilization through the resource scaling method
+in response to complex and changing workflow requests.
+Experimental evaluations show that our ARAS, ranging
+from Montage to LIGO workflows, obtain better perfor-
+mances than the baseline algorithm for various metrics
+under different workflow arrival patterns (Table 2). Fur-
+thermore, we have shown that the KubeAdaptor detects
+and handles failure situations of resource allocation in Sec-
+tion 6.2.2. The self-healing and self-configuration abilities of
+the KubeAdaptor (mentioned in 4.3) are also fully verified.
+In our future work, we intend to use KubeAdaptor to ana-
+lyze different resource allocating algorithms and try to use
+deep reinforcement learning method to investigate cloud
+resource allocation for cloud workflows. In addition, we will
+study resource allocation strategies suitable for a cloud-edge
+cooperation environment and provide a practical solution
+for cloud-edge task scheduling.
+ACKNOWLEDGMENTS
+This work was supported in part by the National Natural
+Science Foundation of China (Grant No. 61873030 and No.
+62002019), and the Beijing Institute of Technology Research
+Fund Program for Young Scholars.
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+SHAN Chenggang was born 1982. He received
+the M.S. degree in computer applied technol-
+ogy from Qiqihr University, China, in 2007. He
+is working toward the Ph.D. degree with the
+School of Automation, Beijing Institute of Tech-
+nology, Beijing, China. He was an associate pro-
+fessor with the School of Artificial Intelligence,
+Zaozhuang University, China, in 2017. His re-
+search interests include networked control sys-
+tems, cloud computing, cloud-edge collabora-
+tion, wireless networks.
+E-mail: uzz scg@163.com
+
+18
+WU Chuge was born in 1993. She received the
+B.E degree in automatic control from Tsinghua
+University, Beijing, China, in 2015, and the M.S.
+and Ph.D. degrees in control theory and its appli-
+cations from Tsinghua University, Beijing, China,
+in 2021. She was a Visiting Scholar with the
+University of Sydney, NSW, Australia, in 2018.
+She is currently a Assistant Processor for the
+School of Automation, Beijing Institute of Tech-
+nology. She has published 13 research papers
+in peer-reviewed journals and conferences. Her
+current research interests include the scheduling and optimization the-
+ory and algorithms for cloud computing, fog computing systems, real-
+time scheduling, and evolutionary algorithms.
+E-mail: wucg@bit.edu.cn
+XIA Yuanqing was born in 1971. He received
+his Ph.D. degree in control theory and control
+engineering from Beijing University of Aeronau-
+tics and Astronautics, Beijing, China, in 2001.
+From January 2002 to November 2003, he was
+a postdoctoral research associate with the Insti-
+tute of Systems Science, Academy of Mathemat-
+ics and System Sciences, Chinese Academy of
+Sciences, Beijing, China. From November 2003
+to February 2004, he was with National Univer-
+sity of Singapore as a research fellow, where he
+worked on variable structure control. From February 2004 to February
+2006, he was with University of Glamorgan, Pontypridd, U.K., as a
+research fellow. From February 2007 to June 2008, he was a guest pro-
+fessor with Innsbruck Medical University, Innsbruck, Austria. Since 2004,
+he has been with School of Automation, Beijing Institute of Technology,
+Beijing, first as an associate professor, then, since 2008, as a professor.
+His research interests include networked control systems, robust control
+and signal processing, and active disturbance rejection control.
+E-mail: xia yuanqing@bit.edu.cn
+GUO Zehua was born in 1985. He received
+B.S. degree from Northwestern Polytechnical
+University, Xi’an, China, M.S. degree from Xid-
+ian University, Xi’an, China, and Ph.D. degree
+from Northwestern Polytechnical University. He
+was a Research Fellow at the Department of
+Electrical and Computer Engineering, New York
+University Tandon School of Engineering, New
+York, NY, USA, and a Research Associate at
+the Department of Computer Science and En-
+gineering, University of Minnesota Twin Cities,
+Minneapolis, MN, USA. His research interests include programmable
+networks (e.g., software-defined networking, network function virtualiza-
+tion), machine learning, and network security. Dr. Guo is an Associate
+Editor for IEEE Systems Journal and the EURASIP Journal on Wireless
+Communications and Networking (Springer), and an Editor for the KSII
+Transactions on Internet and Information Systems. He is serving as
+the TPC of several journals and conferences (e.g., Elsevier Computer
+Communications, AAAI, IWQoS, ICC, ICCCN, ICA3PP). He is a Senior
+Member of IEEE, China Institute of Communications, Chinese Institute
+of Electronics, and a Member of ACM and China Computer Federation.
+E-mail: guo@bit.edu.cn
+LIU Danyang was born in 1993. He received
+the B.S. degree in mathematics and information
+science from the Shijiazhuang University, Shiji-
+azhuang, China, in 2016, and the M.S. degree
+from Hebei University of Science and Technol-
+ogy University, Shijiazhuang, China, in 2020. He
+is currently pursuing the Ph.D. degree in control
+science and engineering from the School of Au-
+tomation, Beijing Institute of Technology, Beijing,
+China. His research interests include cloud com-
+puting and data center networks.
+E-mail: liudanyang093@163.com
+ZHANG Jinhui was born in 1982. He received
+the Ph.D. degree in Control Science and Engi-
+neering from Beijing Institute of Technology, Bei-
+jing, China, in 2011. He was a Research Asso-
+ciate in the Department of Mechanical Engineer-
+ing, University of Hong Kong, Hong Kong, from
+February 2010 to May 2010, a Senior Research
+Associate in the Department of Manufacturing
+Engineering and Engineering Management, City
+University of Hong Kong, Hong Kong, from De-
+cember 2010 to March 2011, and a Visiting Fel-
+low with the School of Computing, Engineering & Mathematics, Uni-
+versity of Western Sydney, Sydney, Australia, from February 2013 to
+May 2013. He was an Associate Professor in the Beijing University
+of Chemical Technology, Beijing, from March 2011 to March 2016,
+a Professor in the School of electrical and automation engineering,
+Tianjin University, Tianjin, from April 2016 to September 2016. He joined
+Beijing Institute of Technology in October 2016, where he is currently
+an Tenured Professor. His research interests include networked control
+systems and composite disturbance rejection control.
+E-mail: zhangjinh@bit.edu.cn
+
diff --git a/0tFAT4oBgHgl3EQfCRy0/content/tmp_files/load_file.txt b/0tFAT4oBgHgl3EQfCRy0/content/tmp_files/load_file.txt
new file mode 100644
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf,len=2671
+page_content='1  Adaptive Resource Allocation for Workflow  Containerization on Kubernetes  SHAN Chenggang, WU Chuge, XIA Yuanqing,GUO Zehua,LIU Danyang, and ZHANG Jinhui  Abstract—In a cloud-native era, the Kubernetes-based workflow engine enables workflow containerized execution through the inherent  abilities of Kubernetes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' However, when encountering continuous workflow requests and unexpected resource request spikes, the  engine is limited to the current workflow load information for resource allocation, which lacks the agility and predictability of resource  allocation, resulting in over and under-provisioning resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This mechanism seriously hinders workflow execution efficiency and  leads to high resource waste.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' To overcome these drawbacks, we propose an adaptive resource allocation scheme named ARAS for  the Kubernetes-based workflow engines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Considering potential future workflow task requests within the current task pod’s lifecycle, the  ARAS uses a resource scaling strategy to allocate resources in response to high-concurrency workflow scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The ARAS offers  resource discovery, resource evaluation, and allocation functionalities and serves as a key component for our tailored workflow engine  (KubeAdaptor).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' By integrating the ARAS into KubeAdaptor for workflow containerized execution, we demonstrate the practical abilities  of KubeAdaptor and the advantages of our ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Compared with the baseline algorithm, experimental evaluation under three distinct  workflow arrival patterns shows that ARAS gains time-saving of 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8% to 40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='92% in the average total duration of all workflows, time-saving  of 26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4% to 79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='86% in the average duration of individual workflow, and an increase of 1% to 16% in CPU and memory resource usage  rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Index Terms—Resource Allocation, Workflow Containerization, Kubernetes, Workflow Management Engine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  1  INTRODUCTION  W  ITH the advent of a cloud-native era, the most  popular virtualization solution is using Docker  1  for container encapsulation with Kubernetes (K8s) [1] for  multi-host container orchestrating.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Docker and K8s 2 have  become mainstream tools for cloud resource management  and dominated the whole cloud-native technology ecosys-  tem [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Workflows have been widely applied in scientific  computing communities such as astronomy, bioinformatics,  material science, and earth science [3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' A scientific workflow  is commonly formulated as a directed acyclic graph (DAG),  which consists of dozens of workflow tasks (represented  by nodes) and dependencies among tasks (indicated by  directed edges).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' A DAG abstracts a particular scientific  computing process through shared data files between tasks  and predefined task dependencies [4], [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Powered by  Docker and K8s, cloud infrastructure features the scalability  and high availability of computational resources [6] and  is especially suitable as a running platform for scientific  workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Scientific workflows usually serve large-scale applica-  tions and require a considerable amount of resources to  execute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Efficient resource allocation is a key issue in work- C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Shan and D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Liu are with the School of Automation, Beijing Institute  of Technology, Beijing 100081, China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Shan is also with the School of  Artificial Intelligence, Zaozhuang University, Zaozhuang 277100, China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  E-mail: {uzz scg, liudanyang093}@163.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Wu, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Xia, Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Guo and J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Zhang are with the School of Automation,  Beijing Institute of Technology, Beijing 100081, China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' E-mail: {wucg,  xia yuanqing, guo, zhangjinh}@bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cn  (Corresponding author: Jinhui Zhang)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' http://docs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='docker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://kubernetes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='io/  flow execution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Existing workflow management engines  like Nextflow [7], Pagasus [8], [9], Galaxy [10], and Argo  workflow engine  3 can execute hundreds of workflows  on cloud infrastructure and be responsible for assigning  computational resources to workflow tasks [11].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When en-  countering continuous workflow requests and unexpected  resource request spikes, the computational resource require-  ments of workflows can be highly dynamic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The ever-  changing resource requirements of workflows bring a great  administrative burden to the workflow engines for resource  allocation and seriously decrease the execution efficiency of  workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' On the one hand, the permanent provision of  fixed computational resources will cope with peak loads in  a resource-intensive scenario but incur high costs and re-  source over-provisioning, as resources are not fully utilized  during off-peak times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' On the other hand, some workflows  may not be executed at all and suffer from a poor Quality of  Service (QoS) due to insufficient resource provisions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In order to avoid over and under-provisioning of re-  sources, some existing works propose reasoning [12], [13],  feedback [14], heuristics [15], learning and prediction mod-  els [16], [17], [18], [19] to cope with resource allocation in  cloud environment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Although these solutions can partially  address the cloud resource allocation problem, they com-  monly use prior knowledge of cloud systems to cope with  resource allocation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As a result, these solutions might play  to their strengths in a specific application scenario, but they  are not fully adaptable to the K8s-based cloud environment  with dynamic resource requirements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Besides, numerous it-  eration training may result in high computational complex-  ity and resource overheads in learning and prediction mod-  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' http://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/argoproj/argo  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='08409v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='DC]  20 Jan 2023  2  els.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Therefore, with the application platform and technology  stack in mind, they do not fit with the K8s-based workflow  management engines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The bottleneck here is the absence of a  high-efficiency adaptive resource allocation scheme that can  help the K8s-based workflow management engines to make  appropriate resource provisions in response to continuous  workflow requests and unexpected request resource spikes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In  our  former  work  [20],  [21],  we  presented  the customized K8s-based  workflow  management  en-  gine (KubeAdaptor), able to integrate workflow systems  with K8s and implement workflow containerization on K8s  cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In this paper, we present an adaptive resource alloca-  tion scheme (ARAS) that follows the Monitor-Analyse-Plan-  Execute Knowledge (MAPE-K) model [22], [23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The ARAS  periodically responds to the task pod’s resource request and  uses the resource discovery algorithm, resource evaluation  algorithm, and resource allocation algorithm to complete  the resource allocation of this round task by the resource  scaling strategy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We reconstruct and extend KubeAdaptor,  and implement ARAS as the Resource Manager component  of KubeAdaptor, which consists of a Resource Discovery  module, Resource Evaluator module, and Allocator mod-  ule.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Three modules complement each other to achieve the  adaptive resource allocation (refers to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' First, the  Resource Discovery module invokes the resource discovery  algorithm to obtain the remaining resources (such as CPU  and memory) of K8s cluster nodes and the resource usage  of running task pods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Then the Resource Evaluator module  integrates the remaining resources of the K8s cluster and  workflow workloads from the Redis database and evalu-  ates resource adequacy for the K8s cluster nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Finally,  the Allocator module uses a resource scaling strategy (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=',  vertical autoscaling) [24] to make resource provisions for  current active task pods in response to continuous workflow  requests and sudden request spikes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We have open-sourced  the proposed ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The source code is publicly available  on GitHub 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  This paper focuses on adaptation, that is, the adap-  tive adjustment of resource allocation in the context of  changing workflow resource requirements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Compared with  the baseline algorithm, experimental evaluation of running  four scientific workflows under three different workflow  arrival modes shows that ARAS gains time-saving of 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8%  to 40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='92% in the average total duration of all workflows,  time-saving of 26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4% to 79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='86% in the average duration of  individual workflow, and an increase of 1% to 16% in CPU  and memory resource usage rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The main contributions of  this paper are summarized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' MAPE-K architecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' With the MAPE-K mecha-  nism  as  a  core,  we  decouple  and  reconstruct  the KubeAdaptor and integrate our ARAS into  four  phases  of  the  MAPE-K  model  to  equip  the  KubeAdaptor  with  self-healing  and  self-  configuration abilities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' A novel monitoring mechanism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We devise and de-  velop a resource discovery algorithm through the  K8s resource characteristics and Informer component.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  The Resource Discovery module uses this algorithm  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/CloudControlSystems/ResourceAllocation  to build a novel monitoring mechanism to collect all  related data in K8s clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Automation deployment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We modularize and imple-  ment the four steps of the proposed ARAS with loose  coupling in mind so that the users can easily mount  a newly designed algorithm module to replace an ex-  isting one with minimal intrusion into the workflow  management engine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Better performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' With the help of K8s and the  MAPE-K mechanism, we use ARAS to conduct a  wealth of experiments on four scientific workflows  on K8s clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Our ARAS shows better perfor-  mance compared to the baseline algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  The rest of the paper is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Section 2  introduces related work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Section 3 elaborates on the system  model and problem formulation, while Section 4 further  describes our system architecture and components.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Section  5 illustrates the implementation of our adaptive resource  allocation scheme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Section 6 describes the experimental  setup and discusses the evaluation results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Finally, Section  7 concludes this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2  RELATED WORK  The resource allocation scheme in the workflow manage-  ment engine is influenced by the virtualization technology  of cloud infrastructure, which is directly related to whether  workflow tasks are hosted by VM instances or containers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In this section, we review the development of resource  allocation strategy and discuss three categories of resource  allocation strategy from the perspective of the evolution  of virtualization technology, namely VM-based, Container-  based, and Cloud-native-based.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Note that the analysis of  each aspect is not completely limited to the scope of the  workflow management engine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  VM-based resource allocation  In the VM-based era, Lee et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [25] propose an adap-  tive scheduling approach to adjust resource allocation and  scheduling in the Pegasus workflow management system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  This approach utilizes batch queues to assign jobs to clus-  ter’s VMs and optimizes job scheduling across cluster’s  VMs through the average queue time of each available  VM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Islam et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [26] develop prediction-based resource  measurement and provisioning strategies using neural net-  works and linear regression to satisfy upcoming resource  demands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The sliding window approach for predicting re-  source usage in the cloud fits with dynamic and proactive  resource management for interactive e-commerce applica-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As for Business Process Management System (BPMS)  field, Hoenisch et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [12] present a self-adaptive resource  allocation approach to automatically lease and release cloud  resources for workflow executions based on knowledge (re-  source usage in VMs) about current and future process  landscape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This approach has been implemented as part of  ViePEP, a BPMS able to manage and schedule workflows  in the cloud.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' By monitoring resource usage of VMs and  the QoS of individual service invocations in VMs, ViePEP  uses a prediction model to provide resource provisioning  for elastic process execution of workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Subsequently,  3  Hoenisch et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [13] extend ViePEP by dynamic workflow  scheduling and resource allocation algorithms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The pro-  posed algorithm not only provides a complete schedule plan  based on their former predicting model but also moves the  service invocations (workflow task) from one timeslot to  another to fully utilize the acquired resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Although these solutions present appropriate cloud re-  source allocation schemes to some extent, the predictive  models commonly require the collection and modeling ac-  cording to former data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' These upfront preparations consume  unnecessary resources and block the automatic operation  flow of the workflow management engines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Besides, VMs-  based resource allocation schemes are commonly limited to  VM’s features such as slow startup, clumsy deployment,  and high resource consumption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Therefore, these schemes  are not suitable for performing workflows with dynamic  and ever-changing resource requirements in cloud infras-  tructures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  Container-based resource allocation  In the Container era, container-based resource allocation  schemes gradually become the mainstream of cloud re-  source management.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Considering the absolute resource iso-  lation and security features of VMs, most container-based  resource allocation scenarios adopt the deployed model of  VM hosting containers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For instance, Mao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [27] propose  a differentiated quality of experience scheduler to adjust  resource provisioning for deep learning applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This  scheduler is implemented into Docker Swarm 5 and can  accept the targeted quality of experience specifications from  clients and dynamically adjust resource limits of contain-  ers to approach performance targets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Abdullah et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [16]  introduce a new deep learning-based approach to estimate  the execution time of the jobs through the collected per-  formance traces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This approach also predicts the execution  time for different CPU pins and uses the laws of dimin-  ishing marginal returns to provide optimal CPU allocation  to Docker containers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In the fog computing community,  Yin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [28] propose a container-based task-scheduling  algorithm with task delay constraint in mind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, a  resource reallocation mechanism works to achieve resource-  utilization maximization on fog nodes by modifying the re-  source quota of task containers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Hu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [29] propose CEC,  a containerized edge computing framework for dynamic  resource provisioning in response to multiple intelligent  applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The CEC first makes resource provisioning for  containers in advance based on the workload prediction  for the edge cluster formed by Docker Swarm and then  uses the idea of control theory to achieve dynamic resource  adjustments (meaning a sufficient number of containers) for  hosted service applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Containers, an efficient and lightweight virtualization  technology, bring significant technology change to VMs-  based resource allocation strategies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' But in fact, it needs a  container orchestration tool (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', Docker Swarm) to manage  a wealth of containers across cluster nodes in several sce-  narios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In practice, resource limits’ adjustment and realloca-  tion of resource quotas in running containers have brought  significant administrative burdens to Docker Swarm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Also,  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://docs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='docker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/engine/swarm/  the adjustments to the number of containers will cause a  delay in the startup of new containers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, the  preparation for predictive models is also not conducive  to the automation of workflow management engines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Due  to the shortcomings of the above solutions and the task  dependencies and high concurrency of workflow, these re-  source allocation strategies can not provide efficient ideas  for container-based workflow management engines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3  Cloud-native-based resource allocation  As the first hosted project by Cloud Native Computing  Foundation (CNCF) 6, K8s has become the de-facto standard  container orchestration system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Docker and K8s are reshap-  ing resource management strategies for cloud infrastruc-  tures in the cloud-native era.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For example, Chang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [30]  propose a generic platform to facilitate dynamic resource  provisioning based on K8s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The platform employs open-  source tools to retrieve all the resource utilization metrics  (such as CPU and memory) while integrating the applica-  tion QoS metrics into monitoring.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The resource scheduler  module in the platform makes dynamic resource provi-  sioning by horizontal scaling of task pods according to  the K8s cluster’s workload.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Mao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [31] investigate the  performance of using cloud-native frameworks (Docker and  K8s) for big data and deep learning applications from the  perspective of resource management fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Together with  Prometheus 7 and Grafana 8, the authors build a container  monitoring system to keep tracking the resource usage of  each job on worker nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' To address massive aggregate re-  source wastage, Google uses Autopilot to configure resources  automatically, adjusting both the number of concurrent  tasks in a job (horizontal scaling) and the CPU/memory lim-  its for individual tasks (vertical scaling) [24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Subsequently,  Bader et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' [11] propose Tarema, a system for allocating task  instances to heterogeneous K8s cluster resources during the  execution of scalable scientific workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Using a scoring  algorithm to determine the best match between a task and  the available resources, Tarema provides the near-optimal  task-resource allocation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  However, most of these resource allocation solutions  in the cloud-native era use open source tools (from the  CNCF community) to build resource monitoring systems,  obtain the required resource utilization of the cluster, and  provide corresponding resource provisioning strategies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It  brings high deployment costs to the workflow management  engine, which is inconsistent with the simple deployment  and automatic system characteristics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, these  tools put too much pressure on the K8s cluster because  of frequent access to kube-apiserver 9 for acquiring cluster  resources [32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  To summarize the related work, we can conclude that  resource allocation policies change with the evolution of  virtualization technologies to adapt to different application  scenarios and technology platforms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The most typical exam-  ple is ViePEP-C [33], which evolved from former work [12],  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://www.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cncf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='io/  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/prometheus/prometheus  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/grafana/grafana  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The API server serves as the front end and is a component of  the K8s control plane that exposes the K8s API.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Its performance is a  weathervane for the overall K8s cluster performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4  [13], [34], [35] in the VMs era to a container-based resilient  BPMS platform in the container era, using containers in-  stead of VMs for the execution of business process activ-  ities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Considering automation and flexible deployment of  the integrated platform, resource allocation technology in  the cloud-native era is more focused on Docker and K8s  platforms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The design of our workflow management engine  follows this idea.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' K8s, with its unique technical advantages  and ecology in scheduling, automatic recovery, horizontal  scalability, resource monitoring, and other aspects, makes its  integration with workflow management engines far beyond  the capabilities of container-based workflow management  engines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Inspired by the work in [24], [27], [31], our ARAS  takes into account workflow loads in K8s clusters and  uses vertical scaling technology of containers to cope with  continuous workflow requests and sudden resource spikes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  3  SYSTEM MODEL  This section describes how to use our ARAS to cope with  continuous workflow requests and unexpected resource re-  quest spikes and maximize resource utilization while meet-  ing workflow Service Level Objectives (SLOs).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  System description  For the clarity of presentation, we consider the scenario of  a single K8s cluster with a set of nodes (VMs), donated by  V = {v1, v2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', vm}, where m represents the number of K8s  cluster nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As for m nodes, we have a set of available  CPU cores C = {c1, c2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', cm} and a set of availble memory  capacity M = {mem1, mem2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='memm} correspondingly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  The workflow set injected into the KubeAdaptor is rep-  resented as W = {w1, w2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', wk}, where k indicates the  amount of workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, a workflow is abstractly  defined as wi = {slawi, si,1, si,2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', si,n}, wherein i in-  dicates the ID of a workflow, slawi represents a Service  Level Agreement (SLA) of a workflow and si,1, si,2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', si,n  indicates steps (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', tasks) of workflow wi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Each workflow  task is defined as  si,j = {slasi,j, id, image, cpu, mem, duration,  mincpu, minmem}, 1 ≤ i ≤ k and 1 ≤ j ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (1)  Herein, id is the unique identifier of this workflow task  in workflow wi, and image represents the Docker Image  address of this workflow task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The cpu is the amount of  CPU Milli cores required by the users, and mem is the  amount of memory capacity required by the users.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' duration  indicates the duration of the task pod running, and mincpu  and minmem represent a minimum of CPU and memory  resources required to run the task container of si,j in work-  flow wi, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Generally, a workflow can have an  optional SLA (slai) composed of several SLOs expressed  by slo1, slo2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', slon on workflow (slawi) or workflow  task (slasi,j) as following:  slai = {slo1, slo2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', slon}, i ∈ {wi, si,j}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (2)  Herein, we only consider the deadline as the single SLO,  meaning that each task in the workflow must be completed  before its respective deadlines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Likewise, this workflow is  no exception.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  slawi = deadlinewi,  slasi,j = deadlinesi,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (3)  Note that the deadline for the last task si,last in a workflow  is identical to this workflow execution deadline:  deadlinesi,last = deadlinewi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (4)  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  Problem formulation  We assume that SLAs and deadlines defined by users are  valid and achievable, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', a properly completed workflow  means that all of its tasks must be completed by the  deadline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' With maximizing the resource utilization in the  K8s cluster as a goal, as long as a task request arrives,  our ARAS uses the resource scaling method to provide  computational resources to the task container.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, the  resource provision of the task container must not be less  than a minimum of running resources to ensure the smooth  operation of the task container.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 1 depicts an execution process of a small-scale Mon-  tage workflow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' At t1 seconds, task request of T1 arrives, and  our ARAS has abilities to acquire concurrent tasks within its  lifecycle (from t1 to t2) considering predefined deadlines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As  can seen from Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 1, T2, T3 and T4 will be launched within  T1’s lifecycle and four workflow tasks will compete for com-  puting resources each other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' To ensure that four concurrent  tasks have enough resources to run smoothly, our ARAS  employs the resource scaling method to reasonably allocate  resources, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', scaling down resource requirements of the  current task T1 according to the ratio of the total resource  requirements of four tasks to the remaining resources in the  K8s cluster (refers to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Similarly, T10 executes between  t2 and t3, T16 executes between t4 and t5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Their respective  lifecycle all contains several concurrent tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The arrival of  each task request also requires the resource scaling method  to allocate resources in line with Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In the following, we elaborate on the optimal problem  in our ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The allocated CPU and memory resources for  each requested task in workflow wi are respectively defined  as follows:  U = {ui,1, ui,2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', ui,n},  R = {ri,1, ri,2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', ri,n}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (5)  xi  y,z ∈ {0, 1} with workflow identifier i is adopted as a  decision variable for task placement, where 1 ≤ y ≤ n and  1 ≤ z ≤ m and defined as  xi  y,z =  �  1  if yth task in wi is scheduled on Node vz,  0  if yth task in wi is not scheduled on Node vz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  We assume that each node in the K8s cluster is always  active and that workflows are continuously injected into  our workflow management engine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Memtotal indicates the  total number of remaining memory resources of the K8s  cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Since CPU is a compressible resource and memory  is an incompressible resource, we only consider memory to  maximize resource allocation in the optimization model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' So  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='our objective function is as follows:  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='t4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='t5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='container  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='VM (K8s Cluster Node)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Legend:  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Resource allocation example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' A small-scale Montage workflow  with 21 tasks is used to illustrate the resource scaling method in our  ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The test environment uses our experimental setup in Sec-  tion 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Maximize :  k  �  i=1  n  �  j=1  ri,j/Memtotal  (6)  Subject to:  m  �  z=1  xi  y,z = 1  k  �  i=1  n  �  y=1  xi  y,j · ui,y ≤ cj  k  �  i=1  n  �  y=1  xi  y,j · ri,y ≤ memj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (7)  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (6) shows the objective function in our model, which  maximizes the resource utilization for the remaining mem-  ory of the K8s cluster at each moment of the task request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (7) shows three constraints of our model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The first  constraint indicates that a task can be scheduled on only one  cluster node.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The last two constraints imply that the total  CPU and memory resources consumed by all task pods on  the hosted node vj must be less than or equal to the amount  of the respective available resources on that node.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4  ARCHITECTURE  This section presents the system architecture of KubeAdap-  tor in detail, including its framework, design logic, and key  modules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Subsequently, the MAPE-K model is elaborated  around the resource allocation mechanism of KubeAdaptor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  KubeAdaptor framework  The KubeAdaptor for the ARAS is illustrated in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As  a workflow management engine, it works to administrate,  schedule, and execute containerized workflow tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Its core  functionalities are as follows: Provide an interface to the public or private cloud,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  allowing to customize workflows on demand Implement the containerized execution of workflows  following the precedence and dependency relation-  ships Adaptively allocate resource quotas for requested  workflow tasks and maximize resource utilization  when ensuring the SLAs of workflows Provide the ability of flexible deployment and the  automatic operation flow and integrate into the K8s  platform  With the assistance of ARAS in this paper,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' KubeAdaptor  equips with the functionalities of a cloud resource man-  agement system to elegantly manage a potentially highly  volatile cloud workflow application scenario.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  KubeAdaptor modules  As depicted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 2, KubeAdaptor consists out of three  main top level entities, including a Command Line Inter-  face (CLI), a Workflow Injection Module and a Containerized  Workflow Builder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The Containerized Workflow Builder com-  prises seven sub-components responsible for workflow re-  ception, containerization, resource allocation, resource mon-  itoring, and task container cleanup.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We focus on the Resource  manager module related to ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  CLI: It aims to define SLAs-based workflows and offer  configuration files of one-key deployment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, the  users may request many workflows consecutively or even  simultaneously through the CLI module.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Workflow Injection Module: Its Parser and Packaging  modules serve as an independent function pod and work  to read variable configuration information of workflow def-  inition from the mounted directory, parse and encapsulate  workflows in response to generating request of the subse-  quent workflow from the Interface Uint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Interface Uint: This module works on receiving the  workflow generating request, decomposing the workflow  tasks, watching the state changes of task pods or workflows  from the Task Container Cleaner, invoking the Containerized  Executor to generate workflow namespaces and task pods,  and writing workflow status into the Redis database.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Once  the creation of the task pod fails, this module turns to fault  tolerance management [21], also known as self-healing, the  ability of a system to detect and recover from potential  problems and continue to operate smoothly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Containerized Executor: Its two subcomponents work  on generating workflow namespaces and task pods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This  module creates task pods through allocated resources from  the Resource Manager.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, the states of workflows  and task pods are timely written into the Redis database.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Resource Manager: It contains three subcomponents,  such as Resource Discovery, Resource Evaluator and Alloca-  tor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The Resource Discovery is responsible for acquiring the  remaining resource of the overall K8s cluster from the  Informer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The Resource Evaluator obtains workflow resource  requirements and workflow execution states from the Redis  database, assesses the adequacy of the current remaining  resources of the K8s cluster, and launches corresponding  countermeasures, if necessary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The Allocator module uses  resource scaling strategy to make resource allocation for  current active task pods in response to continuous workflow  requests and sudden request spikes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It is also known as  self-configuration, the ability of a system to reconfigure itself  under changing and unpredictable circumstances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Informer: As a core toolkit in Client go 10, the Informer  is in charge of synchronizing resource objects and events  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/kubernetes/client-go  6  Workflow  Injection  Module  Parser  Packaging  config.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='yaml  wf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='yaml  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Command Line  Interface (CLI)  Interface  Unit  Namespace  Creator  Task Container  Creator  Containerized Executor  Volume  Volume  Resource  Discovery  Resource  Evaluator  Allocator  Resource Manager  Redis  State Tracker  Task Container  Cleaner  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  K8s Cluster  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  K8s Cluster  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  K8s Cluster  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  KubeAdaptor  Containerized Workflow Builder  Informer  Workflow  Injection  Module  Parser  Packaging  config.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='yaml  wf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='yaml  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Command Line  Interface (CLI)  Interface  Unit  Namespace  Creator  Task Container  Creator  Containerized Executor  Volume  Resource  Discovery  Resource  Evaluator  Allocator  Resource Manager  Redis  State Tracker  Task Container  Cleaner  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  K8s Cluster  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Node n  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  K8s Cluster  Node 2  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  Node 1  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  task pod  task pod  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  KubeAdaptor  Containerized Workflow Builder  Informer  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' KubeAdaptor architecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Monitoring  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Analysis  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Planning  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Execution  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Remaining resources and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Allocated resources  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='New plan  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Informer  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Redis  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Remaining  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='resources and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='workflow status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='K8s Cluster  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Injection  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Module  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Interface  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Unit  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Containerized  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Executor  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Command Line  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='deploy  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Resource Manager  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='State Tracker  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Task Container  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Cleaner  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Watch resource  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='objects  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Trigger  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='next task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Create task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pods  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Write workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Acquire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='MAPE-K Model  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Update  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Watch task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pod  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Analysis  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Informer  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Redis  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='Command Line  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Interface (CLI)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='deploy  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Resource Manager  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='State Tracker  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Task Container  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Cleaner  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Concrete workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Resource Allocation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Delete completed task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Abstract workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Watch resource  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='objects  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Synchronize  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='resource status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Trigger  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='next task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Create task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pods  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Write workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='data  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Acquire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='resources  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='MAPE-K Model  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Update  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='data  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Watch task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pod  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='KubeAdaptor  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Monitoring  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Analysis  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Planning  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Execution  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Remaining resources and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Allocated resources  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='New plan  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Informer  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Redis  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Remaining  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='resources and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='workflow status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='K8s Cluster  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Injection  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Module  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Interface  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Unit  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Containerized  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Executor  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Command Line  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Interface (CLI)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='deploy  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Resource Manager  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='State Tracker  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Task Container  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Cleaner  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Concrete workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Resource Allocation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Delete completed task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Abstract workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Watch resource  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='objects  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Synchronize  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='resource status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Trigger  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='next task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Create task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pods  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Status  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Write workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='data  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Acquire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='resources  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='MAPE-K Model  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Update  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='workflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='data  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Watch task  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pod  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='KubeAdaptor  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Resource allocation scheme based on MAPE-K model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  between K8s core components and Informer local cache.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  It provides the Resource Discovery with the remaining re-  sources of the K8s cluster and responds to the State Tracker  for the state changes of the resource objects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  State Tracker: It hosts the monitoring program based  on the List-Watch mechanism and responds state queries of  various resource objects to each module anytime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Task Container Cleaner: It works on deleting the pods  in a state of Succeeded or Failed or OOMKilled and workflow  namespaces without uncompleted task pods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Once receiving  successful feedback on the just-deleted workflow or task  pods, this module proceeds to Interface Unit and triggers  the following workflow or subsequent task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Redis: The Redis database is to be deployed within  or outside the cluster in advance and is responsible for  storing workflow execution status and predefined resource  requirements of workflow tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  KubeAdaptor is implemented by the Go language and  provides an CLI interface to K8s clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' With just a few  tweaks to the configuration file, the users can go out of  the box and smoothly deploy the KubeAdaptor on K8s  clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The deployment and uninstalling of KubeAdaptor  are non-intrusive and clean to the cluster, and its workflow  containerization execution works in an automated way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For  further details about KubeAdaptor, we refer to [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3  MAPE-K model  The MAPE-K model [36], originated from the field of Auto-  matic Computing, is an instrumental framework for system-  atic development of adaptive systems, including resource al-  location and workflow adaptation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Adaptive strategy within  the KubeAdaptor works to realize the self-optimization  of resource utilization maximization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, the self-  optimization ability, along with self-healing and self-  configuration (elaborated in 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2), enables our KubeAdaptor  to become a self-management system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  To deal with persistent workflow requests and ever-  changing resource requirements, we use the MAPE-K model  to retrofit with minimal intervention to the KubeAdaptor,  which forms an adaptive execution cycle as depicted in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In the following, we will briefly discuss the four steps  of this cycle and how they influence the self-management  capabilities of KubeAdaptor:  Monitoring: The Monitoring functionalities stem from  the Informer and Redis database and work to provide work-  flow status and the remaining resources in K8s Clusters  to the next step.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Workflow status data includes which  workflows have been executed, which tasks have been com-  pleted, resource requirements of workflow tasks, as well as  the SLOs of the workflow and task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The remaining resources  refer to the residual CPU and memory resources of the K8s  cluster and each node in the K8s cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Analysis: The functionality of this step comes into play  in the Resource Evaluator and Allocator within Resource Man-  ager.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For adaptive resource allocation, it is necessary to  analyze the monitored data and reason on the general  knowledge about the system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It is done so that we can  adapt according to countermeasures to deal with dynamic  workflow requests and SLA violations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Planning: The planning step takes full account of the  resource requirements for future workflow tasks to be  launched within the current task lifecycle and SLAs of  workflows to carry out reasoning and generate a resource  allocation plan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The planning results also provide sufficient  prior knowledge for subsequent workflow input to the CLI  module.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Execute: The execution steps are put into practice  through Containerized Executor, aiming to finish the creation  of a new round of task pods combined with the analysis  results of the MAPE-K model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  7  Knowledge Base: While not really a part of the cycle, the  Knowledge Base stores the configuration information about  the system and provides workflow execution status and the  remaining resources in K8s clusters to the MAPE-K model  running.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In short, the KubeAdaptor needs to provide further  analysis of the resource allocation scheme to self-optimize  application scenarios in response to persistent workflow  requests and sudden resource spikes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  5  ADAPTIVE RESOURCE ALLOCATION SCHEME  Once Resource Manager receives a resource request of work-  flow task from Containerized Executor, its three subcompo-  nents immediately launch resource discovery, resource eval-  uation, and resource allocation in turn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The entire execution  process responds to the workflow task’s resource request  iteratively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Next, we introduce the adaptive resource alloca-  tion algorithm, resource discovery algorithm, and resource  evaluation algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' All notations used in our algorithm  are illustrated in Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, workflow execution  states are represented as a set of state data for all tasks of  workflow wi (1 ≤ i ≤ k) and a record of task-state data is  defined as  taskredis  i,j  = {tstart, duration, tend, cpu, mem, flag},  1 ≤ i ≤ k, 1 ≤ j ≤ n and flag ∈ {false, true}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (8)  Note that as long as KubeAdaptor starts, taskredis  i,j  is  stored in Redis database through Interface Unit, and then is  continuously updated by the Containerized Executor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein,  tstart is the start time of the current task pod in K8s cluster,  duration is similar to the definition of si,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='duration and  represents the duration of the current task pod’s running,  tend is the completed time of the current task in the K8s  cluster, cpu and mem are equivalent to the definition of  si,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu and si,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem, and flag is a boolean variable that  identifies the execution status of the current task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Herein, the boolean variable false indicates that the cur-  rent task is not complete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We use Dictionary data structure  Map < taski,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='id, taskredis  i,j  > to indicate state data of the  current task, and taski,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='id is the unique identifier passed  by task si,j of workflow wi (refers to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Because the pod is the minimum execution unit of the  K8s container orchestrator, coupled with KubeAdaptor’s  non-invasive automated execution process, Resource Man-  ager allocates resources only once throughout the requested  task pod’s lifecycle in response to task pod’s resource re-  quest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The users can initially set mincpu and minmem of the  task pod in CLI module, by which this task pod ensures its  hosted container runs smoothly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Algorithm 1 AdaptiveResourceAllocationAlgorithm  Input: si,j;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Output: allocatedcpu, allocatedmem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  1: Initialization:  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu,  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem,  Recpu  max,  Remem  max , totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu, totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem ← 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2: for each task pod’s resource request do  3:  /* Access the Redis and get the total of requested resources  of all pods to be launched within si,j’s lifecycle */  4:  Get taskreq with respects to si,j of wi from Redis;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  5:  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu ← taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6:  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem ← taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  7:  Get all taskredis  i,j  for all workflows from Redis;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  8:  for each task ∈ {taskredis  i,j  } do  9:  if task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='tstart∈[taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='tstart, taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='tend) then  10:  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu += task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  11:  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem += task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  12:  end if  13:  end for  14:  /* Call the ResourceDiscoveryAlgorithm */  15:  ResidualMap ← ResourceDiscoveryAlgorithm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  16:  for each item ∈ ResidualMap do  17:  totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu += item.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  18:  totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem += item.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  19:  if item.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu >Recpu  max then  20:  Recpu  max = item.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  21:  Remem  max = item.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  22:  end if  23:  end for  24:  /* Call the ResourceEvaluationAlgorithm */  25:  allocatedcpu, allocatedmem ←  26:  ResourceEvaluationAlgorithm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  27:  if (allocatedcpu ≥ si,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mincpu) and  28:  (allocatedmem ≥ si,j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='minmem + β)  29:  break;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  30:  end if then  31: end for  32: return allocatedcpu, allocatedmem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  Adaptive resource allocation algorithm  Algorithm 1 presents an adaptive resource allocation algo-  rithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It initializes these parameters to be 0 in line 1 and  takes workflow task si,j as input.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Once the Containerized  Executor sends a task pod’s resource request, the AdaptiveRe-  sourceAllocationAlgorithm performs the following process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Lines 4-13 work to access the Redis database and get the  total of requested resources of all task pods to be launched  within si,j’s lifecycle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' These task pods have resource compe-  tition with the currently requested task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Subsequently,  Algorithm 1 uses ResourceDiscoveryAlgorithm (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2) to obtain  the remaining resources about the K8s cluster and each  node in the K8s cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Lines 16-23 traverse the remaining  resource structure ResidualMap and accumulate to get the  total remaining resources of all nodes across the K8s cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Meanwhile, the proposed algorithm obtains the maximal  remaining CPU and memory resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, we assume  that one node with the maximal remaining CPU resources  also has the maximal remaining memory to facilitate the  conditional comparison in ResourceEvaluationAlgorithm (pri-  oritize CPU resource for allocation).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Then, the proposed  algorithm calls ResourceEvaluationAlgorithm to present the  allocated resources (line 25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  To ensure the task pod run properly in our experimental  testbed, with the running program via Stress tool within the  task pod in mind, we add a constant β to the minimum  running resource for the task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It is because that Stress  tool in the running program of task pod uses minmem to  allocate and release memory resources for resource loads.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Resource amount minmem + β as a minimum of memory  8  TABLE 1  Major notations used in adaptive resource allocation scheme  Notation  Meaning  vi  a K8s node (VM) vi ∈ V  si,j  the jth task in workflow wi, 1 ≤ i ≤ k and 1 ≤ j ≤ n  allocatedcpu  the allocated CPU resource number through the Adaptive Resource Allocation Algorithm  allocatedmem  the allocated memory resource number through the Adaptive Resource Allocation Algorithm  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  the accumulated CPU resource number for many task requests  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  the accumulated memory resource number for many task requests  Recpu  max  the maximum remaining resource amount of CPU among K8s cluster nodes  Remem  max  the maximum remaining resource amount of memory among K8s cluster nodes  totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  the total of residual CPU resource across K8s cluster nodes  totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  the total of residual memory resource across K8s cluster nodes  taskreq  the current task request with respects to si,j  taskredis  i,j  a record of task-state data from Redis database  PodLister  an interface of acquiring pod list in Informer component  NodeLister  an interface of acquiring node list in Informer component  ResidualMap  a data dictionary for storing remaining resources (CPU and memory) of each node  nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  the accumulated CPU resource requirements for all pods on a node  nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  the accumulated memory resource requirements for all pods on a node  allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  the accumulated allocatable CPU resource across K8s cluster nodes  allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  the accumulated allocatable memory resource across K8s cluster nodes  residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  the residual CPU resource in K8s cluster  residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  the residual memory resource in K8s cluster  podi  a data struct from Podlist, which contains many key fields about container’s features  cpucut  the allocated CPU resource amount for task request based on Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9)  memcut  the allocated memory resource amount for task request based on Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9)  α  a proportional value derived from experience, α ∈ (0, 1)  β  a constant value derived from experience, β ≥ 20  resource is just enough to run the task pods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Finally, the  allocated resources returned by the proposed algorithm  meet the conditions of minimum resource demands (line  27).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Algorithm 2 ResourceDiscoveryAlgorithm  Input: PodLister, NodeLister, ResidualMap,;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Output: ResidualMap;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  1: Initialization:  nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu,  nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem,  allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu,  allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem,  residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu,  residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem ← 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2: Get the PodList from PodLister through Informer;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  3: Get the NodeList from NodeLister through Informer;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4: for node vi ∈ V do  5:  /*obtain the total resource requests of all pods on vi*/  6:  for each pod pi in PodList do  7:  if pi is hosted in vi then  8:  if podi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='phase ∈ {Running, Pending} then  9:  nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu += podi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  10:  nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem += podi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  11:  end if  12:  end if  13:  end for  14:  /*obtain the allocatable resources on each node vi*/  15:  Obtain nodei from NodeList corresponding to vi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  16:  allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = nodei.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  17:  allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = nodei.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  18:  /*acquire the remaining resources on node vi*/  19:  residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu - nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  20:  residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = allocatable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem - nodeReq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  21:  /*encapsulate Dictionary ResidualMap*/  22:  ResidualMap[vi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='ip]={residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu, residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem};' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  23: end for  24: return ResidualMap;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  Resource discovery algorithm  Algorithm 2 shows how our resource discovery algorithm  acquires the remaining resources of the K8s cluster and  returns the remaining resource MapResidualMap.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' At first  step, this algorithm initializes related parameters to be 0 in  line 1 and respectively get the PodList and NodeList of K8s  cluster from PodLister and NodeLister through Informer  component.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Then the algorithm traverses all nodes in the  K8s cluster and uses for-loop (lines 6-13) to acquire the total  number of occupied resources for all pods with Running  and Pending states on the current node vi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Lines 15-17  obtain the residual CPU and memory resources on the cur-  rent vi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Next, the algorithm encapsulates the ResidualMap  for each vi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Once the iteration is complete for all the K8s  cluster nodes, the algorithm returns the residual resource  ResidualMap.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3  Resource evaluation algorithm  Algorithm 3 elaborates the resource evaluation process  in detail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The algorithm takes taskreq, Recpu  max, Remem  max ,  totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu, totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem, request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu and  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem as input and finally return the allocated CPU  and memory resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As mentioned in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1), some task  pods to be launched during the requested task pod’s life-  cycle will compete for computational resources with the  current task request taskreq, and we use a resource scaling  method to provide resource allocation based on a propor-  9  tional value of the total remaining resources over the total  amount of resource requests, defined as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  cpucut = (taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu) · totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  ,  memcut = (taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem) · totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (9)  In addition, we define a resource allocation factor α for  each node with a maximum of residual resources (CPU or  memory).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Through lots of experimental evaluations, we use  α = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8, which means that the algorithm only allocates 80%  of the remaining resources in response to insufficient resid-  ual resource scenario on the current node while ensuring  20% residual resources for its other loads.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Algorithm 3 ResourceEvaluationAlgorithm  Input: taskreq, Recpu  max, Remem  max , totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu,  totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu, request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Output: allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu, allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  1: Get cpucut and memcut through Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  2: define  conditions  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu<totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  as  A1,  request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem<totalResidual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  as  A2,  taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu<Recpu  max as B1, taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem<Remem  max  as  B2, cpucut<Recpu  max as C1, and memcut<Remem  max as C2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  3: define the symbol ¬ as the negation of a condition and  the symbol ∧ as the logical and.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  4: /* (1) The remaining resources are sufficient */  5: if A1 ∧ A2 then  6:  if B1 ∧ B2 then  7:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  8:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  9:  else  10:  if ¬B1 ∧ B2 then  11:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = Recpu  max · α  12:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  13:  else  14:  if B1 ∧ ¬B2 then  15:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  16:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = Remem  max · α  17:  else  18:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = Recpu  max · α  19:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = Remem  max · α  20:  end if  21:  end if  22:  end if  23: end if  24: /* (2) The remaining cpu resource is unsufficient */  25: if ¬A1 ∧ A2 then  26:  if C1 ∧ B2 then  27:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = cpucut  28:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  29:  else  30:  if ¬C1 ∧ B2 then  31:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = Recpu  max · α  32:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem  33:  else  34:  if C1 ∧ ¬B2 then  35:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = cpucut  36:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = Remem  max · α  37:  else  38:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = Recpu  max · α  39:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = Remem  max · α  40:  end if  41:  end if  42:  end if  43: end if  44: /* (3) The remaining memory resource is unsufficient */  45: if A1 ∧ ¬A2 then  46:  if B1 ∧ C2 then  47:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  48:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = memcut  49:  else  50:  if ¬B1 ∧ C2 then  51:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = Recpu  max · α  52:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = memcut  53:  else  54:  if B1 ∧ ¬C2 then  55:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu  56:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = Remem  max · α  57:  else  58:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = Recpu  max · α  59:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = Remem  max · α  60:  end if  61:  end if  62:  end if  63: end if  64: /* (4) Both residual resources are unsufficient */  65: if ¬A1 ∧ ¬A2 then  66:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu = cpucut  67:  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem = memcut  68: end if  69: return allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu, allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Algorithm 3 first uses resource scaling to obtain allocated  CPU and memory resources by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9) and defines six  comparative conditions A1, A2, B1, B2, C1 and C2 (lines  1-2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The symbol ¬ denotes the negation of the condition  and the symbol ∧ denotes the logical and (line 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Then  the algorithm implements four resource allocation scenarios  according to comparative conditions between accumulated  resource requests (concurrent scenario) within the current  task lifecycle and the total residual resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Sufficient residual resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When the total residual  resources across the K8s cluster are abundant for concurrent  tasks within the current task lifecycle, we only think about  B1 and B2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When the CPU and memory resource requests of  the current taskreq are smaller than the maximum remain-  ing resources of a node (meets B1 and B2), the algorithm  allocates resources in the light of the current task request  taskreq (lines 6-8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' If the maximum remaining CPU resource  on the cluster node fails to suffice for the current task request  taskreq, the algorithm allocates Recpu  max · α of the maximum  remaining CPU resource on cluster node (lines 10-12).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Con-  versely, so is memory (lines 14-16).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When neither of the two  remaining resources on cluster node (CPU and memory) can  satisfy taskreq, both types of allocated resources scale down  by multiplying α (lines 17-19).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Insufficient residual CPU resource.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When the total  residual CPU resource across the K8s cluster cannot satisfy  the total resource demand of concurrent tasks, conditions  C1 and B2 are considered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The algorithm acquires the cpucut  10  through the resource scaling method (Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In case of con-  ditions C1 and B2, we allocate resources according to cpucut  and taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem (lines 26-28).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When the maximum CPU re-  maining resources of a node fail to accommodate cpucut, the  algorithm adopts Recpu  max · α as the allocated CPU resource.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Due to sufficient memory capacities, the algorithm suffices  for the current task memory request taskreq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem (lines 30-  32).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In case of conditions C1 ∧ ¬B2, the algorithm allocates  cpucut CPU resource and Remem  max · α memory resource,  which is due to that the current task memory request is  greater than the maximum residual memory resource on  cluster node (lines 34-36).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Instead, the algorithm allocates  resources (CPU and memory) according to the α scale factor  of the largest node’s remaining resources (lines 37-39).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Insufficient residual memory resource.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When the total  residual memory resource across the K8s cluster cannot  satisfy the total resource demand of concurrent tasks, condi-  tions B1 and C2 are considered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The algorithm acquires the  memcut through the resource scaling method (Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The  operations under conditions B1 ∧ C2, ¬B1 ∧ C2, B1 ∧ ¬C2  and ¬B1 ∧ ¬C2 are similar to the above, except that here  we are talking about memory resource (lines 45-63).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Insufficient residual CPU and memory resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In  the case of ¬A1 ∧ ¬A2, meaning that the total remaining  CPU and memory resources across the K8s cluster fail  to suffice for the CPU and memory resource requests of  concurrent tasks, the algorithm allocates CPU and memory  resources according to cpucut and memcut obtained by  resource scaling method (lines 65-67).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Finally, ResourceEvalu-  ationAlgorithm returns allocated resources allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cpu and  allocated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='mem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6  EXPERIMENTAL EVALUATION  In the following, we evaluate the proposed ARAS for differ-  ent evaluation metrics and discuss the benefits of the pro-  posed ARAS under three distinct arrival patterns compared  with the baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  Experimental setup and design  For the evaluation, we apply a setting employed in our  former work [21] and make adaptations for the proposed  ARAS within KubeAdaptor discussed here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In this subsec-  tion, we briefly introduce experimental scenarios, work-  flow examples, workflow instantiation, workflow arrival  patterns, evaluation metrics, and baseline algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  Experimental scenarios  The K8s cluster used in our experiments consists of one  Master node and six nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Each node equips with an 8-core  AMD EPYC 7742 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2GHz CPU and 16GB of RAM, running  Ubuntu 20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4 and K8s v1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6 and Docker version 18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='09.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  The Redis database v5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='7 is installed on the Master node.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Workflow Injector Module and Containerized Workflow Builder  are containerized and deployed into the K8s cluster through  Service 11 and Deployment 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We explore the performances of  the proposed ARAS and baseline by running four scientific  workflows on the K8s cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://kubernetes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='io/docs/concepts/  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://kubernetes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='io/docs/concepts/workloads/  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  Workflow examples  To verify the adaptations of our proposed ARAS within  KubeAdaptor, four scientific workflows, such as Mon-  tage (astronomy), Epigenomics (genome sequence), Cyber-  Shake (earthquake science), and LIGO Inspiral (gravita-  tional physics), are used to run on K8s cluster in a con-  tainerized manner [3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We make a few tweaks to the work-  flow structure and add virtual entrance and exit nodes of  workflows to form the workflow structure with the DAG  diagram.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As for each type of scientific workflow, we uni-  formly adopt a small-scale workflow (about 20 tasks) in our  experiments, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 4, derived from the Pegasus  Workflow repository [37].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Structurally, four types of work-  flows cover all the structural features regarding composition  and components (in-tree, out-tree, fork-join, and pipeline)  that serve to illustrate the universality and complexity of  workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, we only consider the topologies of four  scientific workflows and do not focus on the real-world  data processing of the tasks, which does not affect verifying  the adaptability of our ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For ease of performance  comparisons among resource allocation solutions, we as-  sume that four classes of scientific workflows consist of the  same tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Each node of workflow DAGs uses resource  load (CPU and memory utilization) and service runtime to  simulate workflow tasks in the experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Note that the  KubeAdaptor schedules workflow tasks topologically in a  top-down fashion according to task dependencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3  Workflow instantiation  As for resource load in workflow tasks, we employ sev-  eral parameters together with Stress to work on simulating  scientific workflow tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In each task program, we use  the Stress 13 tool to set several CPU forks, a memory of  1000Mi (is equal to memmin of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (1)), and random dura-  tion (user’s definition ahead of time in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' CPU forking  and memory allocation operations in the task pod last twice  as long as duraion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The total duration of each task pod is  random and falls between 10s and 20s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Then we pack the  Python application with Stress program into a task Image  file through Docker Engine 14, store the task Image file in  local Harbor 15 or remote Docker Hub repository 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We can  import container parameters (refer to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (1)) defined in the  ConfigMap file of in Workflow Injection Module into the task  container hosted in the task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For resource setting within  task pod, we uniformly set the resource requests and limits  to 2000 Milli cores (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', 2000m) CPU and 4000Mi memory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Note that the requests field has the same parameter as the  limits field, which ensures that this task pod has the highest  priority, namely Guaranteed [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  Workflow arrival patterns  We make use of three distinct workflow request arrival  patterns:  Constant Arrival Scenario: In this scenario, workflow  requests arrive in a constant manner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Workflow Injector Mod-  uler together with CLI sends 5 workflow requests simulta-  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://linux.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='die.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='net/man/1/stress  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='(a) Montage  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(b) Epigenomics  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(c) CyberShake  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(d) LIGO  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The topology diagram of four scientific workflow applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  neously to the Containerized Workflow Builder every 300 sec-  onds, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', y = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Send six times for a total of 30 workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  A graphical depiction of this arrival curve is depicted in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5(a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Linear Arrival Scenario: In this scenario, the workflow  requests are injected into Containerized Workflow Builder in  a linear rising function, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', y = k ∗ x + d, where y is the  amount of concurrent workflow request and d is the initial  value 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Concurrent workflow requests increase by k = 2  every 300 seconds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This linear arrival curve is depicted in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5(b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Send five times for a total of 30 workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Pyramid Arrival Scenario: In this scenario, workflow  requests are sent to Containerized Workflow Builder in line  with a pyramid-like function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We start with a small number  of concurrent workflow requests (is equal to 2), till it grows  to a randomly selected large number (is equal to 6 for  each type of workflow), which can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Concurrent workflow requests grow every 300 seconds by  2 until the peak is reached.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Once the peak reaches, we  immediately reduce this number to the small initial value  in the same manner and repeat this process until the total  number of workflow requests is reached (herein, 34).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  The deployment of these three scenarios aims to max-  imize coverage of the ever-changing resource needs and  sudden peaks of workflow requests in a production envi-  ronment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Even if there is some predictability in the Constant  and Linear Arrival scenarios, the Pyramid function follows  an unpredictable arrival pattern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  Evaluation metrics  To evaluate our ARAS, we conduct each arrival pattern  three times and analyze the results against the following  quantitative metrics:  Total Duration of All Workflows (in Minutes): This  metric is the average total duration of all injected work-  flows, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', the elapsed time from the arrival of the first  workflow request to the moment when the last workflow  request is complete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Average Workflow Duration (in Minutes): This metric  reflects the average execution time of individual workflow,  which is the time that each workflow takes from the start of  the first task to the end of the last.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Resource Usage: Resource usage contains CPU and  memory resource utilization, reflecting the average resource  utilization throughout the total duration of all injected  workflows across the K8s cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The greater the resource  utilization, the closer to our optimization goal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The resource  usage comparison covering four types of scientific work-  flows with the baseline algorithm further verifies the better  performance of our ARAS solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  Baseline  In experiments, we used our recent resource allocation  strategy [21] as a baseline method, which does not take  into account the potential future task requests throughout  the current task’s lifecycle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It means that the resource al-  location strategy in the baseline follows the First Come  First Serve (FCFS) and relies on the adequacy of residual  resources on cluster nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' If enough, the resource allocation  is complete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Otherwise, wait for other task pods to complete  and release resources to meet the resource reallocation for  the current task request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  Results and analysis  To fully evaluate KubeAdaptor together with our ARAS, we  present a general evaluation and the evaluation of resource  allocation failure, and discuss the evaluation results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In  order to minimize external influences, our K8s cluster has  no other application load, and we execute each evaluation  three times at different times of one day.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1  General evaluation  In the following, we use the KubeAdaptor with our ARAS  and the baseline to run four scientific workflows against  three distinct workflow arrival patterns three times and  compare our ARAS with the baseline on experimental re-  sults.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We calculate the mean value and the standard devia-  tion δ for all metrics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Table 2 presents the resulting mean values and the  standard deviation from the conducted evaluation runs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In general, the observed standard deviation is low and  therefore indicates a low dispersion in the results of the  different evaluations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As presented in Table 2, ”Adaptive”  12  TABLE 2  Evaluation results  Workflow  Metrics  Constant Arrival  Linear Arrival  Pyramid Arrival  Adaptive  Baseline  Adaptive  Baseline  Adaptive  Baseline  Number of Workflow Rquests  30  30  34  Types  Interval between two Requests Bursts (in  Seconds)  300  300  300  Montage  Total Duration of All Workflows in Minutes  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='18  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='79  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='95  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='31  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='69  (Standard Deviation)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='21)  (δ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='26)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='38)  (δ = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='31)  (δ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='46)  (δ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='74)  Average Workflow Duration in Minutes  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='74  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='41  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='33  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='22  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='73  (Standard Deviation)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='49)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='36)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='26)  (δ = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28)  (δ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='36)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='88)  CPU resource Usage  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='27  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='35  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='31  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='26  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  (Standard Deviation)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='00)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='02)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='01)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='07)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='03)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='01)  Memory resource Usage  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='27  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='35  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='26  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='05  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='07  (Standard Deviation)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='09)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='44)  (δ = 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='68)  (δ = 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='88)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15)  (δ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='33)  CPU resource Usage  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='24  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='23  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='31  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='23  (Standard Deviation)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='00)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='02)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='08)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='02)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='01)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='00)  Memory resource Usage  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='24  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='23  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='31  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='23  (Standard Deviation)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='00)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='02)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='08)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='02)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='01)  (δ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='00)  denotes our ARAS, while ”Baseline” marks the application  of the baseline algorithm (mentioned in 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The interval  between two workflow request bursts is set to 300 seconds  for three arrival patterns, and the amount of injected work-  flows for three arrival patterns is set to 30, 30, and 34,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Generally, our ARAS is superior to the baseline algo-  rithm on each observation metric against four different  workflow types under distinct workflow arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In addition, The CPU and memory resources set in the task  pod are constant, the allocatable cluster resources are fixed,  and the resource scaling method scales down resources  according to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' (9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' So no matter in each arrival pattern and  each resource allocation algorithm, the utilization rate of  CPU and memory resources are the same, and both resource  usage curves in each workflow arrival pattern are similar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In  the following, we elaborate on the evaluation metrics of each  workflow arrival pattern in the light of workflow types.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  From Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5 to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 8 illustrate the presentation of the  average evaluation results by depicting the arrival pat-  terns (Workflow Requests) over time and the number of  used computational resources (CPU and memory) until all  workflow requests have been served.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Note that the used  resource curve in each workflow arrival pattern usually  ends later than the workflow request curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It can be traced  to the fact that each workflow has a deadline in the future,  and some workflows are still waiting in queue for execution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Montage: In our experimental setup, a small-scale Mon-  tage workflow consists of 21 tasks (refers to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 4(a)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Compared with the baseline, as for the total duration of  all workflows in Table 2, our ARAS leads to time savings  of 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8% for the constant arrival pattern and time savings of  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='06% for the linear arrival pattern, while in the pyramid  arrival pattern, time savings amounts to 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Similarly, as  for average workflow duration, our ARAS, in comparison to  the baseline, gains a time saving of 26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4%, time savings of  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3%, and time savings of 38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5% for three different work-  flow arrival patterns from left to right, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5  broadly reflects the consistency of the above data with the  total duration of all injected workflows,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' even with a set of  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='13  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(a) Constant Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(b) Linear Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(c) Pyramid Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The CPU and memory resource usage rate under three distinct arrival patterns for Montage workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  evaluation data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Our ARAS achieves better performances in  total workflow duration and average workflow duration in  linear arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It can be deduced that the concurrent  degree of received workflow requests is directly related to  the total duration of all injected workflows and the average  duration of a single workflow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The higher the concurrent  degree of received workflow requests, the more workflow  tasks are executed per unit time, so the shorter the total  duration of all injected workflows and the average duration  of individual workflow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Regarding the CPU and memory resource usage in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5,  our ARAS outperforms the baseline for each arrival pattern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Herein, the linear arrival pattern features a maximum value  of 35% for our ARAS, 4% higher than the baseline algo-  rithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Our ARAS outperforms the baseline algorithm by  1% and 6%, respectively, in the other two patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It can  be traced back to the fact that over time the linear arrival  pattern requests more task pods to be performed in parallel  in response to more and more workflow requests and gains  a maximum resource usage rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Looking at the resource usage curves (CPU and memory)  of three workflow arrival patterns in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5, the resource  usage peak of our ARAS is higher than that of the baseline  algorithm for most of the time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It can be further observed  that the peak of the resource usage curve is consistent with  the centralized arrival of workflow requests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It is because  our ARAS can use a resource scaling strategy to adjust the  resource limits of potential future task requests within the  current task’s lifecycle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' This scheme launches task pods as  many as possible on the premise of the smooth operation  of task pods, thus speeding up the execution efficiency  of workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' However, the baseline algorithm depends  on the adequacy of residual resources on cluster nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In high concurrency scenarios, the insufficient remaining  resources of nodes will make the baseline algorithm lead  to endless waiting and much time-wasting and prolong the  total duration of workflows and the average duration of a  single workflow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Epigenomics: We adopt a small-scale Epigenomics  workflow with 20 tasks in experimental evaluations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As  can be seen from Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 4(b), the topology of Epigenomics  workflows is mostly pipeline structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As for the total  duration of all workflows, our ARAS obtains time savings  of 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8% for the constant arrival pattern, time savings of  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4% for the linear arrival pattern, and time savings of  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2% for the pyramid arrival pattern compared with the  baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As for average workflow duration, our ARAS, in  comparison to the baseline, gains time savings of 54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='65%,  time savings of 40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='65%, and time savings of 50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28% for three  arrival patterns from left to right, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Note that  the Epigenomics workflow is substantially more significant  in performance improvement than the Montage workflow  in terms of average total workflow duration and average  duration of individual workflow for three arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Because the pipeline topology in the Epigenomics workflow  is better suited for high concurrency scenarios, our ARAS  scheme saves more time than the baseline in response to  continuous workflow requests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Regarding the resource usage in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 6, the constant  arrival pattern features a maximum value of 34% for our  ARAS, 7% higher than the baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The linear arrival pat-  tern features a value of 32% for our ARAS, which is also 7%  higher than the baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The higher resource utilization of  these two patterns can be attributed to the fact that 30 work-  flows were injected in the first 25 minutes, totaling more  than 600 tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The higher density of workflow requests  results in higher CPU and memory resource utilization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In  addition,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' the resource scaling method enables our ARAS  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='to adjust the resource limits of the task pods in time and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cope with the continuous workflow requests on the premise  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='14  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(a) Constant Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(b) Linear Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(c) Pyramid Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The CPU and memory resource usage rate under three distinct arrival patterns for Epigenomics workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  of the normal execution of workflow tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It also shows  that the peak time of resource usage in our ARAS is longer  than that of the baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The baseline algorithm waits for  resource release in response to resource shortage on cluster  nodes, so it consumes too much time and results in a longer  total workflow duration and average duration of a single  workflow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  CyberShake: A small-scale CyberShake workflow in our  experiments comprises 22 tasks (refers to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 4(c)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Our  ARAS, in comparison to the baseline, leads to time savings  of 23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8% (for the constant arrival pattern), time savings  of 31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1% (for the linear arrival pattern), and time savings  of 29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6% (for the pyramid arrival pattern) for the total  duration of all workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Similarly, for average workflow  duration, our ARAS, in comparison to the baseline, gains  time savings of 46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='85%, time savings of 54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='34%, and time  savings of 74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='63% for three arrival patterns from left to right,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Due to the topology structure of the CyberShake work-  flow with smaller depth and greater width, the CyberShke  workflow features a higher degree of inherent parallelism,  which is easier to take advantage of our ARAS in response to  continuous workflow request arrivals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Compared with the  baseline algorithm, the ARAS has prominent performance  advantages on metrics of total workflow duration and dura-  tion of a single workflow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' As for CPU and memory resource  usage, our ARAS obtains 26%, 27%, and 22% for three  distinct arrival patterns, respectively, and slightly higher  than the baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Combined with the resource utilization  curve in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 7, it can be observed that our ARAS benefiting  from the resource scaling method outperforms the baseline  in all performance metrics under three different workflow  arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  LIGO: A small-scale LIGO workflow in our experiments  consists of 23 tasks (refers to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 4(d)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Compared with  the baseline, our ARAS gains time savings of 40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='92% (for  the constant arrival pattern), time savings of 18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='28% (for  the linear arrival pattern), and time savings of 28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='79% (for  the pyramid arrival pattern) for the total duration of all  workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Similarly, for average workflow duration, our  ARAS, in comparison to the baseline, gains time savings  of 79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='86%, time savings of 42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='21%, and time savings of  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15% for three arrival patterns from left to right, respec-  tively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' With unique concurrent topology, LIGO workflows,  like Epigenomics and CyberShake workflows, enable our  ARAS to perform better in the total workflow duration  and individual workflow duration metrics than the baseline  algorithm under three different arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  As for resource usage in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 8, our ARAS obtained  40% for the constant arrival pattern, 28% for linear arrival  pattern and 31% for pyramid arrival pattern, respectively,  much higher than the baseline algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In combination  with the resource utilization curve trend, resource scaling  strategy and workflow’s unique concurrency topology once  again help our ARAS outperform the baseline under three  different workflow arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  Evaluation of resource allocation failure  In  this  evaluation,  we  analyze  the  behavior  of  the  KubeAdaptor in a failure situation of resource allocation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  This situation means that our ARAS allocates resource  quotas less than minmem + β through the resource scaling  method against a high-concurrency scenario.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' So the task  pods cannot smoothly execute and turn to OOMKilled  status due to insufficient memory resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Accordingly,  the OOMKilled task pods make the workflow running get  stuck.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The source code of evaluation of resource allocation  failture is available at 17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In the following, we investigate how KuberAdaptor re-  sponds to OOMKilled task pods, reallocates resources to ex-  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com/CloudControlSystems/OOM-Test  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(a) Constant Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(b) Linear Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(c) Pyramid Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The CPU and memory resource usage rate under three distinct arrival patterns for CyberShake workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  ecute task pods, and resumes workflow execution under our  ARAS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' For this evaluation, we inject 10 Montage workflows  into our K8s cluster (mentioned in 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1) at a time under the  constant arrival pattern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' We fine-tune mincpu and minmem  to be less than the amount of memory required by the Stress  tool in the task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Subsequently, our ARAS tries to reduce  the allocated resource quota by the resource scaling method  in response to continuous workflow requests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' When the  allocated resource is less than minmem+β, OOMKilled task  pods will appear due to running resource shortage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 9 depicts the results of this evaluation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 9  the first annotation marker, labeled OOMKilled, signalizes  when the current task pod encounters the OOM (Out of  Memory) event, and the other annotation marker, labeled  Reallocation, signalizes when the current task pod is re-  generated by using the reallocated computational resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  As can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 9, at the beginning (second 0), our  ARAS uses the resource scaling method to allocate CPU of  1048 Milli cores and memory of 2009Mi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In this evalua-  tion, the minimum memory for a task pod to run, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', the  amount of memory operated by the Stress tool in the task  pod is set to 2000Mi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Herein, we only focus on memory  resources because memory resources are incompressible  resources, and insufficient memory resources will trigger the  task pod OOMKilled, while CPU resources as compressible  resources do not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Once the allocated memory resource fails  to reach minmem + β (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', 2000Mi + 20Mi), the current  task pod turns to OOMKilled at 66s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Meanwhile, the work-  flow with the current OOMKilled task pod also terminates  execution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' KubeAdaptor can capture the OOMKilled task  pod and delete the task pod at 66s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In our experimental  evaluation, up to 210 task pods (10 Montage workflows)  possess frequent created and deleted operations, leading  to operation delay of deleting OOMKilled task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' At  97s, KubeAdaptor triggers the regeneration of the current  task pod, reallocates computational resources, and launches  the task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Since the second allocation of resources is  sufficient for the smooth execution of the task pod (1849m  CPU and 3560Mi memory), the task pod is completed at  181s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' At 258s, KubeAdaptor deletes the completed task pod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  KubeAdaptor equipped with our ARAS in this paper  can watch OOMKilled events, delete these OOMKilled task  pods, reallocate computational resources, and regenerate  these OOMKilled task pods, ensuring continuous execution  of workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In production practice, the users inevitably  misestimate the resource quota of the main program inside  workflow tasks, resulting in a large number of OOMKilled  task pods and termination of workflow execution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' These  countermeasures ensure continuous executions of work-  flows and keep the KubeAdaptor stable and robust.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' It also  reflects the self-healing and self-configuration abilities of the  KubeAdaptor (mentioned in 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3  Concluding discussion  Finally, it can be observed that the KubeAdaptor with our  ARAS always achieves better results regarding each met-  ric (Sections 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' From Montage workflows to LIGO work-  flows, our ARAS outperforms the baseline against different  metrics under three distinct workflow arrival patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Most of the time savings from the total workflow du-  ration and average duration of individual workflow result  from the fact that the resource scaling method enables our  ARAS to maximize resource utilization on cluster nodes  according to our optimized functions while ensuring the  smooth running of workflow pods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, the work-  flow topology with concurrent characteristics also plays a  positive role.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Concerning resource allocation failure and workflow  recovery after termination, we have shown in Section 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='that the KubeAdaptor has abilities to watch the state  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='16  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='constant arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(a) Constant Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='linear arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(b) Linear Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='65  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#CPU (Cores)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable cpu  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used cpu in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='50  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='65  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Time (Minutes)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='40  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='60  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='100  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='120  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='#Memory (Gi)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Workflow Requests  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='allocatable memory  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in Adaptive  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='used memory in baseline  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='pyramid arrival pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='(c) Pyramid Arrival Pattern  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The CPU and memory resource usage rate under three distinct arrival patterns for LIGO workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  0  50  100  150  200  250  300  350  400  0  1000  2000  3000  4000  5000  6000  #CPU (Milli Cores)  OOMKilled  Reallocation  allocated cpu of OOMKilled task pod  reallocated cpu of this task pod  0  50  100  150  200  250  300  350  400  Time (Seconds)  0  2000  4000  6000  8000  #Memory (Mi)  OOMKilled  Reallocation  allocated memory of OOMKilled task pod  reallocated memory of this task pod  Minimum memory for the task pod to run  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Evaluation results of resource allocation failure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The first vertical  blue line labeled OOMKilled indicates that this task pod encounters  OOMKilled due to insufficient allocated memory resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Another ver-  tical blue line labeled Reallocation indicates that the task pod previously  OOMKilled is recreated due to sufficient allocated memory resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  changes of task pods in real-time, delete the OOMKilled  task pods, and reallocate computational resources for the  task pod, followed by the re-creation of this OOMKilled  task pod and recover of workflow executing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  7  CONCLUSION  In this paper, we propose an ARAS for our tailored work-  flow management engine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' With the novel architecture of  KubeAdaptor and the integration between KubeAdaptor  and K8s, our ARAS enables the KubeAdaptor to maximize  resource utilization through the resource scaling method  in response to complex and changing workflow requests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Experimental evaluations show that our ARAS, ranging  from Montage to LIGO workflows, obtain better perfor-  mances than the baseline algorithm for various metrics  under different workflow arrival patterns (Table 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Fur-  thermore, we have shown that the KubeAdaptor detects  and handles failure situations of resource allocation in Sec-  tion 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' The self-healing and self-configuration abilities of  the KubeAdaptor (mentioned in 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='3) are also fully verified.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  In our future work, we intend to use KubeAdaptor to ana-  lyze different resource allocating algorithms and try to use  deep reinforcement learning method to investigate cloud  resource allocation for cloud workflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' In addition, we will  study resource allocation strategies suitable for a cloud-edge  cooperation environment and provide a practical solution  for cloud-edge task scheduling.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  ACKNOWLEDGMENTS  This work was supported in part by the National Natural  Science Foundation of China (Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 61873030 and No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  62002019), and the Beijing Institute of Technology Research  Fund Program for Young Scholars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  REFERENCES  [1]  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' BURNS, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' GRANT, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' OPPENHEIMER, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' BREWER, and  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' WILKES, “Borg, omega, and kubernetes,” Communications of the  ACM, vol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 59, no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' 5, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='  [2]  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content=' [Online].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Available: https:  //pegasus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='isi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='edu/workflow gallery  [38] Kubernetes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  (2022)  Configure  quality  of  service  for  pods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  [Online].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  Available:  https://kubernetes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='io/docs/tasks/  configure-pod-container/quality-service-pod  SHAN Chenggang was born 1982.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He received  the M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree in computer applied technol-  ogy from Qiqihr University, China, in 2007.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He  is working toward the Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree with the  School of Automation, Beijing Institute of Tech-  nology, Beijing, China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='E degree in automatic control from Tsinghua  University, Beijing, China, in 2015, and the M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  and Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degrees in control theory and its appli-  cations from Tsinghua University, Beijing, China,  in 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cn  XIA Yuanqing was born in 1971.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He received  his Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree in control theory and control  engineering from Beijing University of Aeronau-  tics and Astronautics, Beijing, China, in 2001.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  From January 2002 to November 2003, he was  a postdoctoral research associate with the Insti-  tute of Systems Science, Academy of Mathemat-  ics and System Sciences, Chinese Academy of  Sciences, Beijing, China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' From November 2003  to February 2004, he was with National Univer-  sity of Singapore as a research fellow, where he  worked on variable structure control.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' From February 2004 to February  2006, he was with University of Glamorgan, Pontypridd, U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', as a  research fellow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' From February 2007 to June 2008, he was a guest pro-  fessor with Innsbruck Medical University, Innsbruck, Austria.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Since 2004,  he has been with School of Automation, Beijing Institute of Technology,  Beijing, first as an associate professor, then, since 2008, as a professor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  His research interests include networked control systems, robust control  and signal processing, and active disturbance rejection control.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  E-mail: xia yuanqing@bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cn  GUO Zehua was born in 1985.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He received  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree from Northwestern Polytechnical  University, Xi’an, China, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree from Xid-  ian University, Xi’an, China, and Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree  from Northwestern Polytechnical University.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He  was a Research Fellow at the Department of  Electrical and Computer Engineering, New York  University Tandon School of Engineering, New  York, NY, USA, and a Research Associate at  the Department of Computer Science and En-  gineering, University of Minnesota Twin Cities,  Minneapolis, MN, USA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' His research interests include programmable  networks (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', software-defined networking, network function virtualiza-  tion), machine learning, and network security.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Dr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' Guo is an Associate  Editor for IEEE Systems Journal and the EURASIP Journal on Wireless  Communications and Networking (Springer), and an Editor for the KSII  Transactions on Internet and Information Systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He is serving as  the TPC of several journals and conferences (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=', Elsevier Computer  Communications, AAAI, IWQoS, ICC, ICCCN, ICA3PP).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He is a Senior  Member of IEEE, China Institute of Communications, Chinese Institute  of Electronics, and a Member of ACM and China Computer Federation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  E-mail: guo@bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cn  LIU Danyang was born in 1993.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He received  the B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree in mathematics and information  science from the Shijiazhuang University, Shiji-  azhuang, China, in 2016, and the M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree  from Hebei University of Science and Technol-  ogy University, Shijiazhuang, China, in 2020.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He  is currently pursuing the Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree in control  science and engineering from the School of Au-  tomation, Beijing Institute of Technology, Beijing,  China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' His research interests include cloud com-  puting and data center networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  E-mail: liudanyang093@163.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='com  ZHANG Jinhui was born in 1982.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He received  the Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' degree in Control Science and Engi-  neering from Beijing Institute of Technology, Bei-  jing, China, in 2011.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He was a Research Asso-  ciate in the Department of Mechanical Engineer-  ing, University of Hong Kong, Hong Kong, from  February 2010 to May 2010, a Senior Research  Associate in the Department of Manufacturing  Engineering and Engineering Management, City  University of Hong Kong, Hong Kong, from De-  cember 2010 to March 2011, and a Visiting Fel-  low with the School of Computing, Engineering & Mathematics, Uni-  versity of Western Sydney, Sydney, Australia, from February 2013 to  May 2013.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He was an Associate Professor in the Beijing University  of Chemical Technology, Beijing, from March 2011 to March 2016,  a Professor in the School of electrical and automation engineering,  Tianjin University, Tianjin, from April 2016 to September 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' He joined  Beijing Institute of Technology in October 2016, where he is currently  an Tenured Professor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content=' His research interests include networked control  systems and composite disturbance rejection control.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='  E-mail: zhangjinh@bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
+page_content='cn' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/0tFAT4oBgHgl3EQfCRy0/content/2301.08409v1.pdf'}
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+arXiv:2301.03737v1  [hep-ph]  10 Jan 2023
+EPHOU-23-001
+Quark hierarchical structures in modular symmetric
+flavor models at level 6
+Shota Kikuchi, Tatsuo Kobayashi, Kaito Nasu,
+Shohei Takada, and Hikaru Uchida
+Department of Physics, Hokkaido University, Sapporo 060-0810, Japan
+Abstract
+We study modular symmetric quark flavor models without fine-tuning. Mass matrices are
+written in terms of modular forms, and modular forms in the vicinity of the modular fixed
+points become hierarchical depending on their residual charges. Thus modular symmetric
+flavor models in the vicinity of the modular fixed points have a possibility to describe
+mass hierarchies without fine-tuning. Since describing quark hierarchies without fine-tuning
+requires Zn residual symmetry with n ≥ 6, we focus on Γ6 modular symmetry in the
+vicinity of the cusp τ = i∞ where Z6 residual symmetry remains. We use only modular
+forms belonging to singlet representations of Γ6 to make our analysis simple. Consequently,
+viable quark flavor models are obtained without fine-tuning.
+
+1
+Introduction
+The origin of quark and lepton flavor structures such as hierarchical masses and mixing angles
+is one of challenging issues in particle physics.
+Indeed, many works were done in order to
+solve the problem. Among such works, modular symmetric flavor models are interesting. In
+these flavor models, the quark and lepton mass matrices are written in terms of modular forms,
+which are holomorphic functions of the modulus τ [1] 1. It is well known that the finite modular
+groups ΓN for N = 2, 3, 4, 5 are isomorphic to the non-Abelian finite groups S3, A4, S4 and
+A5, respectively [17]. This is interesting since the non-Abelian finite groups are long familiar
+in flavor models for quarks and leptons [18–28]. Inspired by this point, the modular symmetric
+lepton flavor models have been proposed in Γ2 ≃ S3 [29], Γ3 ≃ A4 [1], Γ4 ≃ S4 [30] and
+Γ5 ≃ A5 [31, 32]. In addition, modular symmetries at levels 6 [33] and 7 [34] were studied.
+Furthermore, modular forms of other groups were also studied [7,35–38].
+Using these various modular forms, the mass ratios and flavor mixing of quarks and leptons
+have been discussed successfully in these years. Phenomenological studies have been developed
+in many works and interesting results have been obtained [39–78]. However, one needs to fine-
+tune coefficients of modular forms in Yukawa couplings in order to describe the hierarchical
+structure of fermion masses, in particular quark mass hierarchies.
+Describing the lepton flavors without fine-tuning on modular invariant models was proposed
+in Ref. [79].
+Authors focused on the vicinity of three modular fixed points, τ = i, ω (=
+e2πi/3) and i∞ where residual symmetries remain [42]. The values of modular forms become
+hierarchical as close to these modular fixed points due to approximate residual symmetries.
+Then, the hierarchy among values of the modular forms is determined by charges of residual
+symmetries at the modular fixed points. For instance the modular forms of Γ4 ≃ S4 with Z4
+(T-transformation) charges 0, 1, 2 and 3 can take the sizes 1, ε, ε2 and ε3, respectively in the
+vicinity of τ = i∞, where ε expresses the deviation from the modular fixed points. Indeed viable
+lepton models on the double covering groups of ΓN, Γ′
+3 ≃ A′
+4, Γ′
+4 ≃ S′
+4 and Γ5 ≃ A′
+5, were studied
+in Ref. [79]. This is one successful way to generate hierarchical structures without fine-tuning.
+Nevertheless the realization of the quark flavor structure is not straightforward. Experiments
+show mass hierarchies of up sector quarks as mu/mt ∼ 10−5 and mc/mt ∼ 10−2-10−3 and ones
+of down sector quarks as md/mb ∼ 10−3 and ms/mb ∼ 10−2 [80]. Suppose that ε = O(0.1).
+Then, we could explain these mass ratios except mu/mt ∼ 10−5. However, ε5 does not appear
+in the framework of the finite modular group of level N less than 6 since the present residual
+symmetries Z2, Z3 and ZN at τ = i, ω and i∞ do not possess the charge larger than 4.
+Thus describing the quark flavor structure without fine-tuning requires the way generating
+hierarchical mass ratios including ε5 = O(10−5).
+One way is to relax the quark mass eigenvalues by tuning the values of coupling constants in
+Yukawa couplings. In Ref. [81], the quark flavor model with A4 modular symmetry was studied
+and succeeded to generate both up and down sector quark mass hierarchies by adjusting one
+1The modular flavor symmetry was also studied from the top-down approach such as string theory [2–16].
+1
+
+coupling constant ratio denoted by gu/gd to O(10). As a result, quark mass hierarchies originate
+from following two origins,
+(i) The vacuum expectation value (VEV) of the modulus τ (the deviation from the modular
+fixed points),
+(ii) The coupling constants in Yukawa couplings.
+Another way is to introduce the finite modular symmetry including Zn residual symmetry
+with n ≥ 6. In such models, the modular forms in the vicinity of the symmetric points can
+take the sizes 1, ε, · · ·, εn−1 depending on their residual charges. Hence, it may be possible
+to generate mass hierarchies in both up and down sector quarks without fine-tuning using the
+hierarchical values of the modular forms up to ε5. Note that in this way quark mass hierarchies
+simply originate from (i) above. In this paper, we study the modular symmetric quark flavor
+model with the finite modular group of level 6, Γ6 ≃ S3 × A4. The finite modular symmetry
+Γ6 breaks into Z6 (T-transformation) residual symmetry at τ = i∞ and can generate the
+hierarchical values of the modular forms up to ε5 in the vicinity of τ = i∞.
+This paper is organized as follows. In section 2, we study generic aspects for the modular
+symmetric quark flavor models being able to realize both up and down sector quark mass
+hierarchies without fine-tuning along the lines proposed in Ref. [79]. In section 3, we study quark
+flavor models with the finite modular group Γ6. Section 4 is our conclusion. We summarize
+group theoretical aspects of Γ6 in appendix A and the modular forms of level 6 in appendix B.
+2
+Hierarchical quark mass matrices without fine-tuning
+In this section, we present modular symmetric quark flavor models without fine-tuning. We
+start from the following assignment of modular weights to supermultiplets:
+• quark doublets Q = (Q1, Q2, Q3) are assigned into three-dimensional (reducible or irre-
+ducible ) representation of a finite modular group with weight −kQ,
+• up sector quark singlets uR = (u1
+R, u2
+R, u3
+R) are assigned into three-dimensional (reducible
+or irreducible ) representation of a finite modular group with weight −ku,
+• down sector quark singlets dR = (d1
+R, d2
+R, d3
+R) are assigned into three-dimensional (re-
+ducible or irreducible ) representation of a finite modular group with weight −kd,
+• each of up and down sector Higgs fields Hu,d is assigned into one-dimensional representa-
+tions of a finite modular group with weight −kHu,d.
+Note that three-dimensional representations are constructed by combining singlets, doublets
+and triplets of any finite modular groups. The most general form of the superpotential relevant
+2
+
+to up sector quark masses is written as
+Wu =
+�
+ri
+
+Y (kYu)
+ri
+�
+Q1
+Q2
+Q3�
+
+
+α11
+ri
+α12
+ri
+α13
+ri
+α21
+ri
+α22
+ri
+α23
+ri
+α31
+ri
+α32
+ri
+α33
+ri
+
+
+
+
+u1
+R
+u2
+R
+u3
+R
+
+ Hu
+
+
+1
+,
+(1)
+where Y (kYu)
+ri
+denotes the modular forms of irreducible representation ri for weight kYu = kQ +
+ku + kHu. Some of coupling constants αij may be related each other when quark doublets Q
+and/or up sector quark singlets uR belong to multiplets. Similarly the superpotential relevant
+to down sector quark masses is written as
+Wd =
+�
+ri
+
+Y
+(kYd)
+ri
+�
+Q1
+Q2
+Q3�
+
+
+β11
+ri
+β12
+ri
+β13
+ri
+β21
+ri
+β22
+ri
+β23
+ri
+β31
+ri
+β32
+ri
+β33
+ri
+
+
+
+
+d1
+R
+d2
+R
+d3
+R
+
+ Hd
+
+
+1
+,
+(2)
+with kYd = kQ + kd + kHd. They lead to the up and down sector quark mass matrices, Mu and
+Md,
+�
+Q1
+Q2
+Q3�
+Mu
+
+
+u1
+R
+u2
+R
+u3
+R
+
+ =
+�
+ri
+
+Y (kYu)
+ri
+�
+Q1
+Q2
+Q3�
+
+
+α11
+ri
+α12
+ri
+α13
+ri
+α21
+ri
+α22
+ri
+α23
+ri
+α31
+ri
+α32
+ri
+α33
+ri
+
+
+
+
+u1
+R
+u2
+R
+u3
+R
+
+ ⟨Hu⟩
+
+
+1
+, (3)
+�
+Q1
+Q2
+Q3�
+Md
+
+
+d1
+R
+d2
+R
+d3
+R
+
+ =
+�
+ri
+
+Y
+(kYd)
+ri
+�
+Q1
+Q2
+Q3�
+
+
+β11
+ri
+β12
+ri
+β13
+ri
+β21
+ri
+β22
+ri
+β23
+ri
+β31
+ri
+β32
+ri
+β33
+ri
+
+
+
+
+d1
+R
+d2
+R
+d3
+R
+
+ ⟨Hd⟩
+
+
+1
+.
+(4)
+We expect that the coefficients αij and βij are of O(1), because we do not explain quark
+mass hierarchies by using hierarchies of these coefficients. In particular, we restrict all coupling
+constants αij and βij to ±1 and study the realization of the orders of mass ratios and the
+Cabibbo, Kobayashi, Maskawa (CKM) matrix elements. Then free parameter is only the value
+of the modulus τ (and the choices of +1 or −1 in coupling constants αij and βij).
+(mu, mc, mt)/mt
+(1.26 × 10−5, 7.38 × 10−3, 1)
+(md, ns, mb)/mb
+(1.12 × 10−3, 2.22 × 10−2, 1)
+Table 1: Observed values of quark masses [80].
+In order to realize hierarchical quark masses as shown in Table 1 without fine-tuning, it is
+necessary to generate hierarchies by values of the modular forms. Actually such hierarchical
+values of the modular forms can be realized in a vicinity of three modular fixed points, τ = i,
+ω and i∞. This can be understood as follows. As an example let us consider Zn symmetric
+point and quark doublets Q, up sector quark singlets uR and up-type Higgs field Hu with the
+following Zn residual charges,
+Q : (1, n − 1, 0),
+uR : (1, 0, 0),
+Hu : 0.
+(5)
+3
+
+Then the entities of the up sector quark mass matrix, Mij
+u , must have the following Zn residual
+charges to make Lagrangian modular invariant,
+Mij
+u :
+
+
+n − 2
+n − 1
+n − 1
+0
+1
+1
+n − 1
+0
+0
+
+ .
+(6)
+In the vicinity of Zn symmetric point, the modular forms with Zn residual charge q, f(τ), can
+be expanded by the deviation from the symmetric point to the power of q [79]:
+1. τ ∼ i: f(τ) ∼ εq, ε ≡ τ−i
+τ+i,
+2. τ ∼ ω: f(τ) ∼ εq, ε ≡
+τ−ω
+τ−ω2,
+3. τ ∼ i∞: f(τ) ∼ εq, ε ≡ e−2πImτ/N (N is a level of the finite modular group).
+Thus the above up sector quark mass matrix can be evaluated as
+Mij
+u ∼
+
+
+εn−2
+εn−1
+εn−1
+1
+ε
+ε
+εn−1
+1
+1
+
+ ,
+(7)
+in the vicinity of Zn symmetric point. Similarly, for the down sector quark mass matrix as
+well as lepton mass matrices, the modular forms take hierarchical values depending on their
+residual charges and lead to hierarchical mass matrices as close to the modular fixed points.
+In Ref. [79], lepton flavor models without fine-tuning around the vicinity of the modular fixed
+points was studied.
+On the other hand, it is difficult to realize quark mass hierarchies by the values of the
+modular forms in the vicinity of τ = i and ω. To realize both up and down sector quark mass
+hierarchies in Table 1 simultaneously, we may need ε to the fifth power, when ε = O(0.1). Hence
+we need five different residual charges. This requirement excludes the vicinity of τ = i and ω
+since they correspond to Z2 and Z3 symmetries, respectively. In other words, such hierarchical
+masses can be realized in the vicinity of the cusp τ = i∞ with ZN charge for N ≥ 6.
+Let us discuss the candidates of the modular symmetry.
+As mentioned above the level
+of the modular symmetry must be lager than 5. Here we focus on the levels 6 and 7, that
+is, Γ6 ≃ S3 × A4 and Γ7 ≃ PSL(2, Z7) as the candidates of the modular symmetry. As the
+irreducible representations less than four dimension, Γ7 ≃ PSL(2, Z7) has only one singlet 1
+and two triplets 3 and ¯3 [34]; this variety of irreducible representations may not be enough
+to find the models being able to realize both up and down sector quark masses. In contrast,
+Γ6 ≃ S3 × A4 has six singlets, 10
+0, 10
+1, 10
+2, 11
+0, 11
+1 and 11
+2, three doublets, 20, 21 and 22, and two
+triplets, 30 and 31 [33]. They would be sufficient to find realistic models. In the following, we
+consider the models with Γ6 modular symmetry and realize quark flavors without fine-tuning
+in the vicinity of τ = i∞.
+4
+
+3
+The models with Γ6 modular symmetry
+Here we study the models with Γ6 modular symmetry and realize the quark flavor structure
+without fine-tuning. As we have mentioned in the previous section, we restrict all couplings αij
+and βij to ±1 in quark mass matrices to avoid fine-tuning by them. We study the realization
+of the orders of mass ratios and mixing angles. We use only the modulus τ (and the choices of
++1 or -1 in αij and βij) as a free parameter.
+In Γ6 modular symmetry, ε to the power up to 5 can appear in mass matrices. Indeed six
+Γ6 singlets with six different T-charges correspond to different powers of ε in the vicinity of
+τ = i∞ as shown in Table 2.
+singlet
+10
+0
+11
+2
+10
+1
+11
+0
+10
+2
+11
+1
+T-charge
+0
+1
+2
+3
+4
+5
+order
+1
+ε
+ε2
+ε3
+ε4
+ε5
+Table 2: T-charges of six Γ6 singlets and their orders in the vicinity of τ = i∞.
+To realize the quark flavor structure, let us consider the following four types of mass matrices,
+Type I:
+Mu ∝
+
+
+ε5
+ε3−a+b
+εb
+±ε5+a−b
+±ε3
+±εa
+±ε5−b
+±ε3−a
+±1
+
+ ,
+Md ∝
+
+
+ε3
+ε2−a+b
+εb
+±ε3+a−b
+±ε2
+±εa
+±ε3−b
+±ε2−a
+±1
+
+ ,
+(8)
+Type II:
+Mu ∝
+
+
+ε5
+ε3−a+b
+εb
+±ε5+a−b
+±ε3
+±εa
+±ε5−b
+±ε3−a
+±1
+
+ ,
+Md ∝
+
+
+ε4
+ε2−a+b
+εb
+±ε4+a−b
+±ε2
+±εa
+±ε4−b
+±ε2−a
+±1
+
+ ,
+(9)
+Type III:
+Mu ∝
+
+
+ε5
+ε2−a+b
+εb
+±ε5+a−b
+±ε2
+±εa
+±ε5−b
+±ε2−a
+±1
+
+ ,
+Md ∝
+
+
+ε3
+ε2−a+b
+εb
+±ε3+a−b
+±ε2
+±εa
+±ε3−b
+±ε2−a
+±1
+
+ ,
+(10)
+Type IV:
+Mu ∝
+
+
+ε5
+ε2−a+b
+εb
+±ε5+a−b
+±ε2
+±εa
+±ε5−b
+±ε2−a
+±1
+
+ ,
+Md ∝
+
+
+ε4
+ε2−a+b
+εb
+±ε4+a−b
+±ε2
+±εa
+±ε4−b
+±ε2−a
+±1
+
+ ,
+(11)
+where ± corresponds any possible combinations of signs and a, b ∈ {0, 1, 2, 3, 4, 5}. Note that
+it is always possible to fix the signs of (1,1), (1,2) and (1,3) components to +1 by the basis
+transformation for right-handed quarks. We set powers of ε on diagonal components in up and
+down sector quark mass matrices to (5,3,0) and (3,2,0) for type I, (5,3,0) and (4,2,0) for type
+II, (5,2,0) and (3,2,0) for type III and (5,2,0) and (4,2,0) for type IV in order to realize their
+hierarchical masses. Here, we use only six Γ6 singlets, 10
+0, 10
+1, 10
+2, 11
+0, 11
+1 and 11
+2, as irreducible
+representations to make our analysis simple. Note that again powers of ε in mass matrices are
+determined by Z6 charges of entities of mass matrices. Thus mass matrices of each type can be
+5
+
+led by the following assignments,
+Type I :
+Q = (1b mod 2
+b mod 3, 1a mod 2
+a mod 3, 10
+0), uR = (15−b mod 2
+5−b mod 3, 13−a mod 2
+3−a mod 3, 10
+0), dR = (13−b mod 2
+3−b mod 3, 12−a mod 2
+2−a mod 3, 10
+0),
+(12)
+Type II :
+Q = (1b mod 2
+b mod 3, 1a mod 2
+a mod 3, 10
+0), uR = (15−b mod 2
+5−b mod 3, 13−a mod 2
+3−a mod 3, 10
+0), dR = (14−b mod 2
+4−b mod 3, 12−a mod 2
+2−a mod 3, 10
+0),
+(13)
+Type III :
+Q = (1b mod 2
+b mod 3, 1a mod 2
+a mod 3, 10
+0), uR = (15−b mod 2
+5−b mod 3, 12−a mod 2
+2−a mod 3, 10
+0), dR = (13−b mod 2
+3−b mod 3, 12−a mod 2
+2−a mod 3, 10
+0),
+(14)
+Type IV :
+Q = (1b mod 2
+b mod 3, 1a mod 2
+a mod 3, 10
+0), uR = (15−b mod 2
+5−b mod 3, 12−a mod 2
+2−a mod 3, 10
+0), dR = (14−b mod 2
+4−b mod 3, 12−a mod 2
+2−a mod 3, 10
+0).
+(15)
+On the other hand, it is not always true that mass matrices in four types are definitely realized
+by the above assignments. It depends on weights of the Yukawa couplings. All of the singlet
+modular forms of Γ6 with certain Z6 charges do not exist for weights less than 14 as shown in
+appendix B. For instance, the modular forms of weight 12 belong to 11
+1 do not exist. Yukawa
+couplings of the weights less than 14 can lead to mass matrices with some zeros due to this
+shortage of the modular forms on low weights. We study the case of Yukawa couplings of the
+weight 14 in subsection 3.1 and one of the weights less than 14 in subsection 3.2.
+3.1
+Weight 14
+First of all, we study the models with Yukawa couplings of weight 14 to avoid zero textures in
+mass matrices of four types. We choose τ = 3.2i as a benchmark point of the modulus. At
+weight 14, seven singlet modular forms, Y (14)
+10
+0 , Y (14)
+11
+2i , Y (14)
+10
+1 , Y (14)
+11
+0 , Y (14)
+10
+2 , Y (14)
+11
+1
+and Y (14)
+11
+2ii, exist
+and they are approximated by ε as
+Y (14)
+10
+0 /Y (14)
+10
+0
+= 1 → 1,
+Y (14)
+11
+2i /Y (14)
+10
+0
+= 0.172 → ε,
+(16)
+Y (14)
+10
+1 /Y (14)
+10
+0
+= 0.0208 → ε2,
+Y (14)
+11
+0 /Y (14)
+10
+0
+= 0.00358 → ε3,
+(17)
+Y (14)
+10
+2 /Y (14)
+10
+0
+= 0.000435 → ε4,
+Y (14)
+11
+1 /Y (14)
+10
+0
+= 0.0000746 → ε5,
+(18)
+Y (14)
+11
+2ii/Y (14)
+10
+0
+= 0.00000156 → ε7,
+(19)
+at τ = 3.2i. Note that Y (14)
+11
+2ii ∼ ε7 originates from Y (6)
+11
+0 Y (8)
+10
+2 ∼ ε3 · ε4 while Y (14)
+11
+2i ∼ ε originates
+from Y (6)
+11
+2 Y (8)
+10
+0 ∼ ε · 1. εn for n > 5 can appear when the different modular forms of the same
+irreducible representations exist. In what follows, we ignore Y (14)
+11
+2ii because it belongs to the
+same representation as Y (14)
+11
+2i and Y (14)
+11
+2i >> Y (14)
+11
+2ii.
+6
+
+3.1.1
+Type I: (5,3,0) and (3,2,0)
+The mass matrices of type I are given by
+Mu =
+
+
+
+
+
+α11Y (14)
+11
+1
+α12Y (14)
+13+a−b mod 2
+3+a−b mod 3
+α13Y (14)
+16−b mod 2
+6−b mod 3
+α21Y (14)
+11−a+b mod 2
+1−a+b mod 3
+α22Y (14)
+11
+0
+α23Y (14)
+16−a mod 2
+6−a mod 3
+α31Y (14)
+11+b mod 2
+1+b mod 3
+α32Y (14)
+13+a mod 2
+3+a mod 3
+α33Y (14)
+10
+0
+
+
+
+
+ ,
+(20)
+Md =
+
+
+
+
+
+β11Y (14)
+11
+0
+β12Y (14)
+14+a−b mod 2
+4+a−b mod 3
+β13Y (14)
+16−b mod 2
+6−b mod 3
+β21Y (14)
+13−a+b mod 2
+3−a+b mod 3
+β22Y (14)
+10
+1
+β23Y (14)
+16−a mod 2
+6−a mod 3
+β31Y (14)
+13+b mod 2
+3+b mod 3
+β32Y (14)
+14+a mod 2
+4+a mod 3
+β33Y (14)
+10
+0
+
+
+
+
+ ,
+(21)
+where αij and βij are coupling constants which we restrict to ±1. The hierarchical mass matrices
+in Eq. (8) can be obtained by choosing +1 or −1 appropriately in αij and βij. As a result, we
+find best-fit mass matrices at τ = 3.2i,
+Mu/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+11
+1
+Y (14)
+10
+2
+Y (14)
+11
+0
+Y (14)
+10
+2
+Y (14)
+11
+0
+Y (14)
+10
+1
+−Y (14)
+10
+1
+−Y (14)
+11
+2i
+Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.0000746
+0.000435
+0.00358
+0.000435
+0.00358
+0.0208
+−0.0208
+−0.172
+1
+
+
+∼
+
+
+ε5
+ε4
+ε3
+ε4
+ε3
+ε2
+−ε2
+−ε
+1
+
+ ,
+(22)
+Md/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+11
+0
+Y (14)
+11
+0
+Y (14)
+11
+0
+Y (14)
+10
+1
+−Y (14)
+10
+1
+−Y (14)
+10
+1
+−Y (14)
+10
+0
+Y (14)
+10
+0
+−Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.00358
+0.00358
+0.00358
+0.0208
+−0.0208
+−0.0208
+−1
+1
+−1
+
+
+∼
+
+
+ε3
+ε3
+ε3
+ε2
+−ε2
+−ε2
+−1
+1
+−1
+
+ .
+(23)
+These mass matrices correspond to a = 2, b = 3 and can be realized by
+Q = (11
+0, 10
+2, 10
+0),
+uR = (10
+2, 11
+1, 10
+0),
+dR = (10
+0, 10
+0, 10
+0),
+(24)
+and their mass matrices are written by,
+Mu =
+
+
+
+
+α11Y (14)
+11
+1
+α12Y (14)
+10
+2
+α13Y (14)
+11
+0
+α21Y (14)
+10
+2
+α22Y (14)
+11
+0
+α23Y (14)
+10
+1
+α31Y (14)
+10
+1
+α32Y (14)
+11
+2i
+α33Y (14)
+10
+0
+
+
+
+ ,
+Md =
+
+
+
+
+β11Y (14)
+11
+0
+β12Y (14)
+11
+0
+β13Y (14)
+11
+0
+β21Y (14)
+10
+1
+β22Y (14)
+10
+1
+β23Y (14)
+10
+1
+β31Y (14)
+10
+0
+β32Y (14)
+10
+0
+β33Y (14)
+10
+0
+
+
+
+ ,
+(25)
+7
+
+with the following choises of +1 or −1 in coupling constants,
+
+
+α11
+α12
+α13
+α21
+α22
+α23
+α31
+α32
+α33
+
+ =
+
+
+1
+1
+1
+1
+1
+1
+−1
+−1
+1
+
+ ,
+
+
+β11
+β12
+β13
+β21
+β22
+β23
+β31
+β32
+β33
+
+ =
+
+
+1
+1
+1
+1
+−1
+−1
+−1
+1
+−1
+
+ .
+(26)
+They lead to the following quark mass ratios,
+(mu, mc, mt)/mt = (2.11 × 10−5, 7.07 × 10−3, 1),
+(27)
+(md, ms, mb)/mb = (2.91 × 10−3, 1.97 × 10−2, 1),
+(28)
+and the absolute values of the CKM matrix elements,
+|VCKM| =
+
+
+0.973
+0.231
+0.000681
+0.231
+0.973
+0.0270
+0.00690
+0.0261
+1.00
+
+ .
+(29)
+Results are shown in Table 3. Our purpose is to derive quark masses and mixing angles
+without fine-tuning. Thus, we have fixed αij, βij = ±1 to make our point clear. If we vary
+αij, βij = O(1) without fixing αij, βij = ±1, we can obtain more realistic values. Of course, we
+have ambiguity in normalization of modular forms, although we expect naturally that normal-
+ization factors would not lead a large hierarchy. Our values appear at a high energy scale such
+as the GUT scale. Renormalization group effects change values by some factors, although such
+radiative corrections may be realized by varying αij, βij = O(1).
+Obtained values
+Observed values
+(mu, mc, mt)/mt
+(2.11 × 10−5, 7.07 × 10−3, 1)
+(1.26 × 10−5, 7.38 × 10−3, 1)
+(md, ms, mb)/mb
+(2.91 × 10−3, 1.97 × 10−2, 1)
+(1.12 × 10−3, 2.22 × 10−2, 1)
+|VCKM|
+
+
+
+
+0.973
+0.231
+0.000681
+0.231
+0.973
+0.0270
+0.00690
+0.0261
+1.00
+
+
+
+
+
+
+
+
+0.974
+0.227
+0.00361
+0.226
+0.973
+0.0405
+0.00854
+0.0398
+0.999
+
+
+
+
+Table 3: The mass ratios of the quarks and the absolute values of the CKM matrix elements
+at the benchmark point τ = 3.2i in the best-fit model by Eqs. (24) and (26) of type I with
+Yukawa couplings of weight 14. Observed values are shown in Ref. [80].
+8
+
+3.1.2
+Type II: (5,3,0) and (4,2,0)
+The mass matrices of type II are given by Eq. (20) and
+Md =
+
+
+
+
+
+β11Y (14)
+10
+2
+β12Y (14)
+14+a−b mod 2
+4+a−b mod 3
+β13Y (14)
+16−b mod 2
+6−b mod 3
+β21Y (14)
+12−a+b mod 2
+2−a+b mod 3
+β22Y (14)
+10
+1
+β23Y (14)
+16−a mod 2
+6−a mod 3
+β31Y (14)
+12+b mod 2
+2+b mod 3
+β32Y (14)
+14+a mod 2
+4+a mod 3
+β33Y (14)
+10
+0
+
+
+
+
+ .
+(30)
+The hierarchical mass matrices in Eq. (9) can be obtained by choosing +1 or −1 appropriately
+in αij and βij. As a result, we find best-fit mass matrices at τ = 3.2i,
+Mu/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+11
+1
+Y (14)
+10
+2
+Y (14)
+11
+0
+Y (14)
+10
+2
+Y (14)
+11
+0
+−Y (14)
+10
+1
+−Y (14)
+10
+1
+−Y (14)
+11
+2i
+−Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.0000746
+0.000435
+0.00358
+0.000435
+0.00358
+−0.0208
+−0.0208
+−0.172
+−1
+
+
+∼
+
+
+ε5
+ε4
+ε3
+ε4
+ε3
+−ε2
+−ε2
+−ε
+−1
+
+ ,
+(31)
+Md/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+10
+2
+Y (14)
+11
+0
+Y (14)
+11
+0
+−Y (14)
+11
+0
+Y (14)
+10
+1
+Y (14)
+10
+1
+Y (14)
+11
+2i
+Y (14)
+10
+0
+−Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.000435
+0.00358
+0.00358
+−0.00358
+0.0208
+0.0208
+0.172
+1
+−1
+
+
+∼
+
+
+ε4
+ε3
+ε3
+−ε3
+ε2
+ε2
+ε
+1
+−1
+
+ .
+(32)
+These mass matrices correspond to a = 2, b = 3 and can be realized by
+Q = (11
+0, 10
+2, 10
+0),
+uR = (10
+2, 11
+1, 10
+0),
+dR = (11
+1, 10
+0, 10
+0),
+(33)
+and their mass matrices are written by,
+Mu =
+
+
+
+
+α11Y (14)
+11
+1
+α12Y (14)
+10
+2
+α13Y (14)
+11
+0
+α21Y (14)
+10
+2
+α22Y (14)
+11
+0
+α23Y (14)
+10
+1
+α31Y (14)
+10
+1
+α32Y (14)
+11
+2i
+α33Y (14)
+10
+0
+
+
+
+ ,
+Md =
+
+
+
+
+β11Y (14)
+10
+2
+β12Y (14)
+11
+0
+β13Y (14)
+11
+0
+β21Y (14)
+11
+0
+β22Y (14)
+10
+1
+β23Y (14)
+10
+1
+β31Y (14)
+11
+2i
+β32Y (14)
+10
+0
+β33Y (14)
+10
+0
+
+
+
+ ,
+(34)
+with the following choises of +1 or −1 in coupling constants,
+
+
+α11
+α12
+α13
+α21
+α22
+α23
+α31
+α32
+α33
+
+ =
+
+
+1
+1
+1
+1
+1
+−1
+−1
+−1
+−1
+
+ ,
+
+
+β11
+β12
+β13
+β21
+β22
+β23
+β31
+β32
+β33
+
+ =
+
+
+1
+1
+1
+−1
+1
+1
+1
+1
+−1
+
+ .
+(35)
+9
+
+They lead to the following quark mass ratios,
+(mu, mc, mt)/mt = (2.14 × 10−5, 7.00 × 10−3, 1),
+(36)
+(md, ms, mb)/mb = (7.16 × 10−4, 2.11 × 10−2, 1),
+(37)
+and the absolute values of the CKM matrix elements,
+|VCKM| =
+
+
+0.982
+0.190
+0.00309
+0.190
+0.982
+0.0200
+0.00683
+0.0191
+1.00
+
+ .
+(38)
+Results are shown in Table 4.
+Obtained values
+Observed values
+(mu, mc, mt)/mt
+(2.14 × 10−5, 7.00 × 10−3, 1)
+(1.26 × 10−5, 7.38 × 10−3, 1)
+(md, ms, mb)/mb
+(7.16 × 10−4, 2.11 × 10−2, 1)
+(1.12 × 10−3, 2.22 × 10−2, 1)
+|VCKM|
+
+
+
+
+0.982
+0.190
+0.00309
+0.190
+0.982
+0.0200
+0.00683
+0.0191
+1.00
+
+
+
+
+
+
+
+
+0.974
+0.227
+0.00361
+0.226
+0.973
+0.0405
+0.00854
+0.0398
+0.999
+
+
+
+
+Table 4: The mass ratios of the quarks and the absolute values of the CKM matrix elements
+at the benchmark point τ = 3.2i in the best-fit model by Eqs. (33) and (35) of type II with
+Yukawa couplings of weight 14. Observed values are shown in Ref. [80].
+3.1.3
+Type III: (5,2,0) and (3,2,0)
+The mass matrices of type III are given by Eq. (21) and
+Mu =
+
+
+
+
+
+α11Y (14)
+11
+1
+α12Y (14)
+14+a−b mod 2
+4+a−b mod 3
+α13Y (14)
+16−b mod 2
+6−b mod 3
+α21Y (14)
+11−a+b mod 2
+1−a+b mod 3
+α22Y (14)
+10
+1
+α23Y (14)
+16−a mod 2
+6−a mod 3
+α31Y (14)
+11+b mod 2
+1+b mod 3
+α32Y (14)
+14+a mod 2
+4+a mod 3
+α33Y (14)
+10
+0
+
+
+
+
+ .
+(39)
+10
+
+The hierarchical mass matrices in Eq. (10) can be obtained by choosing +1 or −1 appropriately
+in αij and βij. As a result, we find best-fit mass matrices at τ = 3.2i,
+Mu/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+11
+1
+Y (14)
+11
+0
+Y (14)
+11
+0
+Y (14)
+10
+2
+−Y (14)
+10
+1
+−Y (14)
+10
+1
+Y (14)
+10
+1
+Y (14)
+10
+0
+−Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.0000746
+0.00358
+0.00358
+0.000435
+−0.0208
+−0.0208
+0.0208
+1
+−1
+
+
+∼
+
+
+ε5
+ε3
+ε3
+ε4
+−ε2
+−ε2
+ε2
+1
+−1
+
+ ,
+(40)
+Md/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+11
+0
+Y (14)
+11
+0
+Y (14)
+11
+0
+Y (14)
+10
+1
+Y (14)
+10
+1
+−Y (14)
+10
+1
+Y (14)
+10
+0
+−Y (14)
+10
+0
+Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.00358
+0.00358
+0.00358
+0.0208
+0.0208
+−0.0208
+1
+−1
+1
+
+
+∼
+
+
+ε3
+ε3
+ε3
+ε2
+ε2
+−ε2
+1
+−1
+1
+
+ .
+(41)
+These mass matrices correspond to a = 2, b = 3 and can be realized by
+Q = (11
+0, 10
+2, 10
+0),
+uR = (10
+2, 10
+0, 10
+0),
+dR = (10
+0, 10
+0, 10
+0),
+(42)
+and their mass matrices are written by,
+Mu =
+
+
+
+
+α11Y (14)
+11
+1
+α12Y (14)
+11
+0
+α13Y (14)
+11
+0
+α21Y (14)
+10
+2
+α22Y (14)
+10
+1
+α23Y (14)
+10
+1
+α31Y (14)
+10
+1
+α32Y (14)
+10
+0
+α33Y (14)
+10
+0
+
+
+
+ ,
+Md =
+
+
+
+
+β11Y (14)
+11
+0
+β12Y (14)
+11
+0
+β13Y (14)
+11
+0
+β21Y (14)
+10
+1
+β22Y (14)
+10
+1
+β23Y (14)
+10
+1
+β31Y (14)
+10
+0
+β32Y (14)
+10
+0
+β33Y (14)
+10
+0
+
+
+
+ ,
+(43)
+with the following choises of +1 or −1 in coupling constants,
+
+
+α11
+α12
+α13
+α21
+α22
+α23
+α31
+α32
+α33
+
+ =
+
+
+1
+1
+1
+1
+−1
+−1
+1
+1
+−1
+
+ ,
+
+
+β11
+β12
+β13
+β21
+β22
+β23
+β31
+β32
+β33
+
+ =
+
+
+1
+1
+1
+1
+1
+−1
+1
+−1
+1
+
+ .
+(44)
+They lead to the following quark mass ratios,
+(mu, mc, mt)/mt = (1.04 × 10−4, 2.12 × 10−2, 1),
+(45)
+(md, ms, mb)/mb = (2.91 × 10−3, 1.97 × 10−2, 1),
+(46)
+and the absolute values of the CKM matrix elements,
+|VCKM| =
+
+
+0.967
+0.255
+0.00000171
+0.255
+0.967
+0.00706
+0.00180
+0.00682
+1.00
+
+ .
+(47)
+11
+
+Results are shown in Table 5.
+Obtained values
+Observed values
+(mu, mc, mt)/mt
+(1.04 × 10−4, 2.12 × 10−2, 1)
+(1.26 × 10−5, 7.38 × 10−3, 1)
+(md, ms, mb)/mb
+(2.91 × 10−3, 1.97 × 10−2, 1)
+(1.12 × 10−3, 2.22 × 10−2, 1)
+|VCKM|
+
+
+
+
+0.967
+0.255
+0.00000171
+0.255
+0.967
+0.00706
+0.00180
+0.00682
+1.00
+
+
+
+
+
+
+
+
+0.974
+0.227
+0.00361
+0.226
+0.973
+0.0405
+0.00854
+0.0398
+0.999
+
+
+
+
+Table 5: The mass ratios of the quarks and the absolute values of the CKM matrix elements
+at the benchmark point τ = 3.2i in the best-fit model by Eqs. (42) and (44) of type III with
+Yukawa couplings of weight 14. Observed values are shown in Ref. [80].
+3.1.4
+Type IV: (5,2,0) and (4,2,0)
+The mass matrices of type IV are given by Eqs. (39) and (30). The hierarchical mass matrices
+in Eq. (11) can be obtained by choosing +1 or −1 appropriately in αij and βij. As a result, we
+find best-fit mass matrices at τ = 3.2i,
+Mu/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+11
+1
+Y (14)
+11
+0
+Y (14)
+10
+0
+Y (14)
+10
+2
+Y (14)
+10
+1
+Y (14)
+11
+1
+Y (14)
+11
+1
+−Y (14)
+11
+0
+−Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.0000746
+0.00358
+1
+0.000435
+0.0208
+0.0000746
+0.0000746
+−0.00358
+−1
+
+
+∼
+
+
+ε5
+ε3
+1
+ε4
+ε2
+ε5
+ε5
+−ε3
+−1
+
+ ,
+(48)
+Md/Y (14)
+10
+0
+=
+
+
+
+
+Y (14)
+10
+2
+Y (14)
+11
+0
+Y (14)
+10
+0
+Y (14)
+11
+0
+−Y (14)
+10
+1
+−Y (14)
+11
+1
+Y (14)
+10
+2
+Y (14)
+11
+0
+−Y (14)
+10
+0
+
+
+
+ /Y (14)
+10
+0
+=
+
+
+0.000435
+0.00358
+1
+0.00358
+−0.0208
+−0.0000746
+0.000435
+0.00358
+−1
+
+
+∼
+
+
+ε4
+ε3
+1
+ε3
+−ε2
+−ε5
+ε4
+ε3
+−1
+
+ .
+(49)
+These mass matrices correspond to a = 5, b = 0 and can be realized by
+Q = (10
+0, 11
+2, 10
+0),
+uR = (11
+2, 11
+0, 10
+0),
+dR = (10
+1, 11
+0, 10
+0),
+(50)
+12
+
+and their mass matrices are written by,
+Mu =
+
+
+
+
+α11Y (14)
+11
+1
+α12Y (14)
+11
+0
+α13Y (14)
+10
+0
+α21Y (14)
+10
+2
+α22Y (14)
+10
+1
+α23Y (14)
+11
+1
+α31Y (14)
+11
+1
+α32Y (14)
+11
+0
+α33Y (14)
+10
+0
+
+
+
+ ,
+Md =
+
+
+
+
+β11Y (14)
+10
+2
+β12Y (14)
+11
+0
+β13Y (14)
+10
+0
+β21Y (14)
+11
+0
+β22Y (14)
+10
+1
+β23Y (14)
+11
+1
+β31Y (14)
+10
+2
+β32Y (14)
+11
+0
+β33Y (14)
+10
+0
+
+
+
+ ,
+(51)
+with the following choises of +1 or −1 in coupling constants,
+
+
+α11
+α12
+α13
+α21
+α22
+α23
+α31
+α32
+α33
+
+ =
+
+
+1
+1
+1
+1
+1
+1
+1
+−1
+−1
+
+ ,
+
+
+β11
+β12
+β13
+β21
+β22
+β23
+β31
+β32
+β33
+
+ =
+
+
+1
+1
+1
+1
+−1
+−1
+1
+1
+−1
+
+ .
+(52)
+They lead to the following quark mass ratios,
+(mu, mc, mt)/mt = (7.46 × 10−5, 1.47 × 10−2, 1),
+(53)
+(md, ms, mb)/mb = (1.01 × 10−3, 1.54 × 10−2, 1),
+(54)
+and the absolute values of the CKM matrix elements,
+|VCKM| =
+
+
+0.974
+0.226
+0.0000000194
+0.226
+0.974
+0.000158
+0.0000358
+0.000154
+1.00
+
+ .
+(55)
+Results are shown in Table 6.
+Obtained values
+Observed values
+(mu, mc, mt)/mt
+(7.46 × 10−5, 1.47 × 10−2, 1)
+(1.26 × 10−5, 7.38 × 10−3, 1)
+(md, ms, mb)/mb
+(1.01 × 10−3, 1.54 × 10−2, 1)
+(1.12 × 10−3, 2.22 × 10−2, 1)
+|VCKM|
+
+
+
+
+0.974
+0.226
+0.0000000194
+0.226
+0.974
+0.000158
+0.0000358
+0.000154
+1.00
+
+
+
+
+
+
+
+
+0.974
+0.227
+0.00361
+0.226
+0.973
+0.0405
+0.00854
+0.0398
+0.999
+
+
+
+
+Table 6: The mass ratios of the quarks and the absolute values of the CKM matrix elements
+at the benchmark point τ = 3.2i in the best-fit model by Eqs. (50) and (52) of type IV with
+Yukawa couplings of weight 14. Observed values are shown in Ref. [80].
+3.2
+Weights less than 14
+Next we study the models with Yukawa couplings of weights less than 14. In this case, some
+of entities in mass matrices vanish because there do not exist modular forms of proper weights
+13
+
+and representations. As an example, let us consider the case that Yukawa couplings for the up
+sector have the weight 8 and ones for the down sector have the weight 10. We choose τ = 3.7i
+as a benchmark point of the modulus. At weight 8, four singlet modular forms, Y (8)
+10
+0 , Y (8)
+11
+2 , Y (8)
+10
+1
+and Y (8)
+10
+2 , exist and they are approximated by ε as
+Y (8)
+10
+0 /Y (8)
+10
+0 = 1 → 1,
+Y (8)
+11
+2 /Y (8)
+10
+0 = −0.0719 → ε,
+(56)
+Y (8)
+10
+1 /Y (8)
+10
+0 = 0.00732 → ε2,
+Y (8)
+10
+2 /Y (8)
+10
+0 = 0.0000535 → ε4,
+(57)
+at τ = 3.7i. At weight 10, five singlet modular forms, Y (10)
+10
+0 , Y (10)
+11
+2 , Y (10)
+10
+1 , Y (10)
+11
+0
+and Y (10)
+11
+1 , exist
+and they are approximated by ε as
+Y (10)
+10
+0 /Y (10)
+10
+0
+= 1 → 1,
+Y (10)
+11
+2 /Y (10)
+10
+0
+= 0.102 → ε,
+(58)
+Y (10)
+10
+1 /Y (10)
+10
+0
+= 0.00732 → ε2,
+Y (10)
+11
+0 /Y (10)
+10
+0
+= 0.000744 → ε3,
+(59)
+Y (10)
+11
+1 /Y (10)
+10
+0
+= 0.00000544 → ε5,
+(60)
+at τ = 3.7i. As a result, we find the following best-fit mass matrices of type III,
+Mu/Y (8)
+10
+0 =
+
+
+
+
+0
+0
+Y (8)
+10
+1
+Y (8)
+10
+2
+Y (8)
+10
+1
+Y (8)
+11
+2
+0
+−Y (8)
+11
+2
+−Y (8)
+10
+0
+
+
+
+ /Y (8)
+10
+0 =
+
+
+0
+0
+0.00732
+0.0000535
+0.00732
+−0.0719
+0
+0.0719
+−1
+
+
+∼
+
+
+0
+0
+ε2
+ε4
+ε2
+−ε
+0
+ε
+−1
+
+ ,
+(61)
+Md/Y (10)
+10
+0
+=
+
+
+
+
+Y (10)
+11
+0
+Y (10)
+11
+0
+Y (10)
+10
+1
+−Y (10)
+10
+1
+−Y (10)
+10
+1
+Y (10)
+11
+2
+Y (10)
+11
+2
+−Y (10)
+11
+2
+Y (10)
+10
+0
+
+
+
+ /Y (10)
+10
+0
+=
+
+
+0.000744
+0.000744
+0.00732
+−0.00732
+−0.00732
+0.102
+0.102
+−0.102
+1
+
+
+∼
+
+
+ε3
+ε3
+ε2
+−ε2
+−ε2
+ε
+ε
+−ε
+1
+
+ .
+(62)
+These mass matrices correspond to a = 1, b = 2 and can be realized by
+Q = (10
+2, 11
+1, 10
+0),
+uR = (11
+0, 11
+1, 10
+0),
+dR = (11
+1, 11
+1, 10
+0),
+(63)
+and their mass matrices,
+Mu =
+
+
+
+
+0
+0
+α13Y (8)
+10
+1
+α21Y (8)
+10
+2
+α22Y (8)
+10
+1
+α23Y (8)
+11
+2
+0
+α32Y (8)
+11
+2
+α33Y (8)
+10
+0
+
+
+
+ ,
+Md =
+
+
+
+
+β11Y (10)
+11
+0
+β12Y (10)
+11
+0
+β13Y (10)
+10
+1
+β21Y (10)
+10
+1
+β22Y (10)
+10
+1
+β23Y (10)
+11
+2
+β31Y (10)
+11
+2
+β32Y (10)
+11
+2
+β33Y (10)
+10
+0
+
+
+
+ ,
+(64)
+14
+
+with the following choises of +1 or −1 in coupling constants,
+
+
+-
+-
+α13
+α21
+α22
+α23
+-
+α32
+α33
+
+ =
+
+
+-
+-
+1
+1
+1
+1
+-
+−1
+−1
+
+ ,
+
+
+β11
+β12
+β13
+β21
+β22
+β23
+β31
+β32
+β33
+
+ =
+
+
+1
+1
+1
+−1
+−1
+1
+1
+−1
+1
+
+ .
+(65)
+They lead to the following up quark and down quark mass ratios,
+(mu, mc, mt)/mt = (1.27 × 10−5, 2.18 × 10−3, 1),
+(66)
+(md, ms, mb)/mb = (1.44 × 10−3, 1.74 × 10−2, 1),
+(67)
+and the absolute values of the CKM matrix elements,
+|VCKM| =
+
+
+0.974
+0.227
+0.00741
+0.227
+0.973
+0.0300
+0.0140
+0.0276
+1.00
+
+ .
+(68)
+Results are shown in Table 7. Thus it is also possible to realize a realistic quark flavor structure
+in the models with Yukawa couplings of weights less than 14 despite some zeros in mass matrices.
+Here we studied the case that Yukawa couplings for the up sector have weight 8 and ones for
+the down sector have weight 10 but other cases may be available for realization of the quark
+flavor structure.
+Obtained values
+Observed values
+(mu, mc, mt)/mt
+(1.27 × 10−5, 2.18 × 10−3, 1)
+(1.26 × 10−5, 7.38 × 10−3, 1)
+(md, ms, mb)/mb
+(1.44 × 10−3, 1.74 × 10−2, 1)
+(1.12 × 10−3, 2.22 × 10−2, 1)
+|VCKM|
+
+
+
+
+0.974
+0.227
+0.00741
+0.227
+0.973
+0.0300
+0.0140
+0.0276
+1.00
+
+
+
+
+
+
+
+
+0.974
+0.227
+0.00361
+0.226
+0.973
+0.0405
+0.00854
+0.0398
+0.999
+
+
+
+
+Table 7: The mass ratios of the quarks and the absolute values of the CKM matrix elements at
+the benchmark point τ = 3.7i in the best-fit model by Eqs. (63) and (65) of type III with up
+sector Yukawa couplings of weight 8 and down sector Yukawa couplings of weight 10. Observed
+values are shown in Ref. [80].
+3.3
+Comment on the origin of Γ6 modular symmetry
+Here we comment on a plausible origin of Γ6 modular symmetry of the theories. For example,
+some modular forms are derived from the torus compactification T 2
+1 ×T 2
+2 ×T 2
+3 of the low-energy
+effective theory of the superstring theory with magnetic flux background [6–11]. The group Γ6
+15
+
+may originate from one of T 2
+i , while the others T 2
+j lead to a trivial symmetry. Alternatively,
+since Γ6 ≃ S3 × A4 ≃ Γ2 × Γ3, it may be expected that Γ2 ≃ S3 originates from one torus T 2
+1
+and Γ3 ≃ A4 originates from another torus T 2
+2 with the moduli stabilization τ1 = τ2 ≡ τ. Then
+T 2
+3 contributes to the group symmetry trivially.
+4
+Conclusion
+We have discussed the possibility to describe mass hierarchies of both up and down sector quarks
+as well as mixing angles without fine-tuning. Describing the quark flavor structure requires Zn
+residual symmetry with n ≥ 6. We have studied the modular symmetric quark flavor models
+of Γ6 ≃ S3 × A4 in the vicinity of the cusp τ = i∞ where Z6 residual symmetry remains. Then
+the values of the modular forms become hierarchical as close to the cusp depending on their Z6
+residual charges.
+In order to obtain viable models, we consider four types of quark mass matrices; the diagonal
+components in up and down sector quark mass matrices are written by ε with the powers of
+(5, 3, 0) and (3, 2, 0) respectively for type I, (5, 3, 0) and (4, 2, 0) for type II, (5, 2, 0) and (3, 2, 0)
+for type III, and (5, 2, 0) and (4, 2, 0) for type IV. The powers of non-diagonal components in up
+and down sector quark mass matrices have been treated as model depending values. When we
+assign the irreducible representations into quarks and Higgs fields, powers of ε in mass matrix
+components are determined by residual charges of mass matrix components. For simplicity, we
+have used only six singlets 10
+0, 10
+1, 10
+2, 11
+0, 11
+1 and 11
+2 as the irreducible representations of Γ6.
+In addition, we have restricted the values of the coupling constants to ±1 to avoid fine-tuning
+by them.
+Firstly, we have investigated the case that up and down sector Yukawa couplings have weight
+14. In such cases, mass matrices have no zeros, that is, all of their components are written in
+terms of the modular forms for Γ6 of weight 14. Consequently, we have obtained viable models
+at τ = 3.2i for each type without fine-tuning.
+Second, we have shown the viable model in the case that Yukawa couplings of the up sector
+have weight 8 and ones of the down sector have weight 10. In this case some components of
+mass matrices can become zero because there do not exist modular forms of proper weights
+and representations. As a result, we have obtained the viable model at τ = 3.7i despite three
+zeros in the up quark mass matrix, Eq. (61).
+Thus, the modular symmetric quark flavor models based on Γ6 in the vicinity of the cusp τ =
+i∞ lead to successful quark mass matrices without fine-tuning. As we have commented in the
+end of previous section, Γ6 ≃ S3 × A4 ≃ Γ2 × Γ3 may originate from the torus compactification
+T 2
+1 ×T 2
+2 ×T 2
+3 of the low-energy effective theory of superstring theory. Motivated this point, the
+modular flavor models based on the direct product of finite modular groups, ΓN1 × ΓN2 × ΓN3,
+may be interesting. Also we can extend our analysis to the lepton sector. We will study them
+in the near future.
+16
+
+In our models, the important parameter is the modulus τ. It must be stabilized such that
+the proper mass hierarchies are realized. We would study such modulus stabilization elsewhere2.
+Acknowledgement
+This work was supported by JSPS KAKENHI Grant Numbers JP22J10172 (SK) and JP20J20388
+(HU), and JST SPRING Grant Number JPMJSP2119(KN).
+Appendix
+A
+Tensor product of Γ6 group
+Here, we give a review on group theoretical aspects of Γ6. The generators of Γ6 are denoted by
+S and T, and they satisfy the following algebraic relations:
+S2 = (ST)3 = T 6 = ST 2ST 3ST 4ST 3 = 1,
+S2T = TS2.
+(69)
+In Γ6 group, there are 12 irreducible representations, six singlets 10
+0, 10
+1, 10
+2, 11
+0, 11
+1 and 11
+2,
+three doublets 20, 21 and 22, two triplets 30 and 31 and one six-dimensional representation 6.
+Each irreducible representation is given by
+1r
+k : S = (−1)r,
+T = (−1)rωk,
+(70)
+2k : S = 1
+2
+�−1
+√
+3
+√
+3
+1
+�
+,
+T = ωk
+�1
+0
+0
+−1
+�
+,
+(71)
+3r : (−1)ra3,
+(−1)rb3,
+(72)
+6 : 1
+2
+� −a3
+√
+3a3
+√
+3a3
+a3
+�
+,
+T =
+�b3
+0
+0
+−b3
+�
+,
+(73)
+where r = 0, 1, k = 0, 1, 2 and
+a3 = 1
+3
+
+
+−1
+2
+2
+2
+−1
+2
+2
+2
+−1
+
+ ,
+b3 =
+
+
+1
+0
+0
+0
+ω
+0
+0
+0
+ω2
+
+ .
+(74)
+In this basis, the Kronecker products between irreducible representations are:
+1r
+i ⊗ 1s
+j = 1t
+m,
+1r
+i ⊗ 2j = 2m,
+1r
+i ⊗ 3s = 3t,
+1r
+i ⊗ 6 = 6,
+(75)
+2i ⊗ 2j = 10
+m ⊕ 11
+m ⊕ 2m,
+2i ⊗ 3r = 6,
+2i ⊗ 6 = 30 ⊕ 31 ⊕ 6,
+(76)
+3r ⊗ 3s = 1t
+0 ⊕ 1t
+1 ⊕ 1t
+2 ⊕ 3t
+1 ⊕ 3t
+2,
+3r ⊗ 6 = 20 ⊕ 21 ⊕ 22 ⊕ 6 ⊕ 6,
+(77)
+6 ⊗ 6 = 10
+0 ⊕ 10
+1 ⊕ 10
+2 ⊕ 11
+0 ⊕ 11
+1 ⊕ 11
+2 ⊕ 20 ⊕ 21 ⊕ 22 ⊕ 30 ⊕ 30 ⊕ 31 ⊕ 31 ⊕ 6 ⊕ 6,
+(78)
+2See for modulus stabilization in modular flavor symmetric models Refs. [82–86] .
+17
+
+where i, j = 0, 1, 2, r, s = 0, 1, m = i + j (mod 3) and t = r + s (mod 2). In the following, we
+show the Clebsch-Gordon (CG) coefficients of these products.
+(α1)1r
+i ⊗
+�β1
+β2
+�
+2j
+= α1P r
+2
+�β1
+β2
+�
+2m
+,
+(α1)1r
+i ⊗
+
+
+β1
+β2
+β3
+
+
+3s
+= α1P i
+3
+
+
+β1
+β2
+β3
+
+
+3t
+,
+(α1)1r
+i ⊗
+
+
+
+
+
+
+
+
+
+β1
+β2
+β3
+β4
+β5
+β6
+
+
+
+
+
+
+
+
+
+6
+= α1P6(r, i)
+
+
+
+
+
+
+
+
+
+β1
+β2
+β3
+β4
+β5
+β6
+
+
+
+
+
+
+
+
+
+6
+,
+�α1
+α2
+�
+2i
+⊗
+�β1
+β2
+�
+2j
+= 1
+√
+2
+(α1β1 + α2β2)10m ⊕ 1
+√
+2
+(α1β2 − α2β1)11m ⊕ 1
+√
+2
+� α1β1 − α2β2
+−α1β2 − α2β1
+�
+2m
+,
+�α1
+α2
+�
+2i
+⊗
+
+
+β1
+β2
+β3
+
+
+3r
+= P6(r, i)
+
+
+
+
+
+
+
+
+
+α1β1
+α1β2
+α1β3
+α2β1
+α2β2
+α2β3
+
+
+
+
+
+
+
+
+
+6
+,
+�α1
+α2
+�
+2i
+⊗
+
+
+
+
+
+
+
+
+
+β1
+β2
+β3
+β4
+β5
+β6
+
+
+
+
+
+
+
+
+
+6
+= P i
+3
+√
+2
+
+
+α1β1 + α2β4
+α1β2 + α2β5
+α1β3 + α2β6
+
+
+30
+⊕ P i
+3
+√
+2
+
+
+α1β4 − α2β1
+α1β5 − α2β2
+α1β6 − α2β3
+
+
+31
+⊕ P6(0, i)
+√
+2
+
+
+
+
+
+
+
+
+
+α1β1 − α2β4
+α1β2 − α2β5
+α1β3 − α2β6
+−α1β4 − α2β1
+−α1β5 − α2β2
+−α1β6 − α2β3
+
+
+
+
+
+
+
+
+
+6
+,
+18
+
+
+
+α1
+α2
+α3
+
+
+3r
+⊗
+
+
+β1
+β2
+β3
+
+
+3s
+= 1
+√
+3(α1β1 + α2β3 + α3β2)1t
+0 ⊕ 1
+√
+3(α1β2 + α2β1 + α3β3)1t
+1
+⊕ 1
+√
+3
+(α1β3 + α2β2 + α3β1)1t
+2 ⊕ 1
+√
+3
+
+
+2α1β1 − α2β3 − α3β2
+−α1β2 − α2β1 + 2α3β3
+−α1β3 + 2α2β2 − α3β1
+
+
+3t
+1
+⊕ 1
+√
+2
+
+
+−α2β3 + α3β2
+−α1β2 + α2β1
+α1β3 − α3β1
+
+
+3t
+2
+,
+
+
+α1
+α2
+α3
+
+
+3r
+⊗
+
+
+
+
+
+
+
+
+
+β1
+β2
+β3
+β4
+β5
+β6
+
+
+
+
+
+
+
+
+
+6
+= P r
+2
+√
+3
+�α1β1 + α2β3 + α3β2
+α1β4 + α2β6 + α3β5
+�
+20
+⊕ P r
+2
+√
+3
+�α1β2 + α2β1 + α3β3
+α1β5 + α2β4 + α3β6
+�
+21
+⊕ P r
+2
+√
+3
+�α1β3 + α2β2 + α3β1
+α1β6 + α2β5 + α3β4
+�
+22
+⊕ P6(r, 0)
+√
+2
+
+
+
+
+
+
+
+
+
+α1β1 − α3β2
+−α2β1 + α3β3
+−α1β3 + α2β2
+α1β4 − α3β5
+−α2β4 + α3β6
+−α1β6 + α2β5
+
+
+
+
+
+
+
+
+
+6
+⊕ P6(r, 0)
+√
+2
+
+
+
+
+
+
+
+
+
+α2β3 − α3β2
+α1β2 − α2β1
+−α1β3 + α3β1
+α2β6 − α3β5
+α1β5 − α2β4
+−α1β6 + α3β4
+
+
+
+
+
+
+
+
+
+6
+,
+19
+
+
+
+
+
+
+
+
+
+
+α1
+α2
+α3
+α4
+α5
+α6
+
+
+
+
+
+
+
+
+
+6
+⊗
+
+
+
+
+
+
+
+
+
+β1
+β2
+β3
+β4
+β5
+β6
+
+
+
+
+
+
+
+
+
+6
+=
+1
+√
+6(α1β1 + α2β3 + α3β2 + α4β4 + α5β6 + α6β5)10
+0
+⊕ 1
+√
+6(α1β2 + α2β1 + α3β3 + α4β5 + α5β4 + α6β6)10
+1
+⊕ 1
+√
+6(α1β3 + α2β2 + α3β1 + α4β6 + α5β5 + α6β4)10
+2
+⊕ 1
+√
+6(α1β4 + α2β6 + α3β5 − α4β1 − α5β3 − α6β2)11
+0
+⊕ 1
+√
+6(α1β5 + α2β4 + α3β6 − α4β2 − α5β1 − α6β3)11
+1
+⊕ 1
+√
+6(α1β6 + α2β5 + α3β4 − α4β3 − α5β2 − α6β1)11
+2
+⊕
+1
+√
+6
+� α1β1 + α2β3 + α3β2 − α4β4 − α5β6 − α6β5
+−(α1β4 + α2β6 + α3β5 + α4β1 + α5β3 + α6β2)
+�
+20
+⊕
+1
+√
+6
+� α1β2 + α2β1 + α3β3 − α4β5 − α5β4 − α6β6
+−(α1β5 + α2β4 + α3β6 + α4β2 + α5β1 + α6β3)
+�
+21
+⊕
+1
+√
+6
+� α1β3 + α2β2 + α3β1 − α4β6 − α5β5 − α6β4
+−(α1β6 + α2β5 + α3β4 + α4β3 + α5β2 + α6β1)
+�
+22
+⊕
+1
+2
+√
+3
+
+
+2α1β1 − α2β3 − α3β2 + 2α4β4 − α5β6 − α6β5
+2α3β3 − α1β2 − α2β1 + 2α6β6 − α4β5 − α5β4
+2α2β2 − α1β3 − α3β1 + 2α5β5 − α4β6 − α6β4
+
+
+30
+⊕ 1
+2
+
+
+α2β3 − α3β2 + α5β6 − α6β5
+α1β2 − α2β1 + α4β5 − α5β4
+−α1β3 + α3β1 − α4β6 + α6β4
+
+
+30
+⊕ 1
+2
+
+
+α2β6 − α3β5 − α5β3 + α6β2
+α1β5 − α2β4 − α4β2 + α5β1
+−α1β6 + α3β4 + α4β3 − α6β1
+
+
+31
+⊕
+1
+2
+√
+3
+
+
+2α1β4 − α2β6 − α3β5 − 2α4β1 + α5β3 + α6β2
+−α1β5 − α2β4 + 2α3β6 + α4β2 + α5β1 − 2α6β3
+−α1β6 + 2α2β5 − α3β4 + α4β3 − 2α5β2 + α6β1
+
+
+31
+⊕
+1
+2
+√
+3
+
+
+
+
+
+
+
+
+
+2α1β1 − α2β3 − α3β2 − 2α4β4 + α5β6 + α6β5
+−α1β2 − α2β1 + 2α3β3 + α4β5 + α5β4 − 2α6β6
+−α1β3 + 2α2β2 − α3β1 + α4β6 − 2α5β5 + α6β4
+−2α1β4 + α2β6 + α3β5 − 2α4β1 + α5β3 + α6β2
+α1β5 + α2β4 − 2α3β6 + α4β2 + α5β1 − 2α6β3
+α1β6 − 2α2β5 + α3β4 + α4β3 − 2α5β2 + α6β1
+
+
+
+
+
+
+
+
+
+6
+⊕ 1
+2
+
+
+
+
+
+
+
+
+
+α2β3 − α3β2 − α5β6 + α6β5
+α1β2 − α2β1 − α4β5 + α5β4
+−α1β3 + α3β1 + α4β6 − α6β4
+−α2β6 + α3β5 − α5β3 + α6β2
+−α1β5 + α2β4 − α4β2 + α5β1
+α1β6 − α3β4 + α4β3 − α6β1
+
+
+
+
+
+
+
+
+
+6
+.
+20
+
+Here we have used the notations,
+P2 =
+� 0
+1
+−1
+0
+�
+,
+P3 =
+
+
+0
+0
+1
+1
+0
+0
+0
+1
+0
+
+ ,
+P6(r, i) =
+� 03
+13
+−13
+03
+�r �P3
+03
+03
+P3
+�i
+.
+(79)
+Further details can be found in Ref. [33].
+B
+Modular forms of Γ6
+Here we give a review on the modular forms of Γ6. The modular forms of level 6 of even weights
+can be constructed from the products of the Dedekind eta function [33],
+η(τ) = q1/24
+∞
+�
+n=1
+(1 − qn),
+q = e2πiτ.
+(80)
+Using η, four linearly independent modular forms of weight 2 can be written down as
+Y (2)
+30 (τ) =
+
+
+−Y 2
+1
+√
+2Y1Y2
+Y 2
+2
+
+ ,
+Y (2)
+11
+2 (τ) = Y3Y6 − Y4Y5,
+Y (2)
+20 (τ) = 1
+√
+2
+�Y1Y4 − Y2Y3
+Y1Y6 − Y2Y5
+�
+,
+(81)
+Y (2)
+6 (τ) = 1
+√
+2
+
+
+
+
+
+
+
+
+
+Y1Y4 + Y2Y3
+√
+2Y2Y4
+−
+√
+2Y1Y3
+Y1Y6 + Y2Y5
+√
+2Y2Y6
+−
+√
+2Y1Y5
+
+
+
+
+
+
+
+
+
+,
+(82)
+where
+Y1(τ) = 3η3(3τ)
+η(τ) + η3(τ/3)
+η(τ) ,
+(83)
+Y2(τ) = 3
+√
+2η3(3τ)
+η(τ) ,
+(84)
+Y3(τ) = 3
+√
+2η3(6τ)
+η(2τ) ,
+(85)
+Y4(τ) = −3η3(6τ)
+η(2τ) − η3(2τ/3)
+η(2τ) ,
+(86)
+Y5(τ) =
+√
+6η3(6τ)
+η(2τ) −
+√
+6η3(3τ/2)
+η(τ/2) ,
+(87)
+Y6(τ) = −
+√
+3η3(6τ)
+η(2τ) + 1
+√
+3
+η3(τ/6)
+η(τ/2) − 1
+√
+3
+η3(2τ/3)
+η(2τ)
++
+√
+3η3(3τ/2)
+η(τ/2) .
+(88)
+21
+
+Then we can construct the modular forms of weight 4 by the CG coefficients shown in appendix
+A as
+Y (4)
+10
+0 (τ) =
+�
+Y (2)
+20 Y (2)
+20
+�
+10
+0
+,
+Y (4)
+10
+1 (τ) =
+�
+Y (2)
+11
+2 Y (2)
+11
+2
+�
+10
+1
+,
+Y (4)
+20 (τ) =
+�
+Y (2)
+20 Y (2)
+20
+�
+20 ,
+(89)
+Y (4)
+22 (τ) =
+�
+Y (2)
+11
+2 Y (2)
+20
+�
+22 ,
+Y (4)
+30 (τ) =
+�
+Y (2)
+20 Y (2)
+6
+�
+30 ,
+Y (4)
+31 (τ) =
+�
+Y (2)
+11
+2 Y (2)
+30
+�
+31 ,
+(90)
+Y (4)
+6i (τ) =
+�
+Y (2)
+11
+2 Y (2)
+6
+�
+6 ,
+Y (4)
+6ii (τ) =
+�
+Y (2)
+20 Y (2)
+30
+�
+6 .
+(91)
+Note that Y (4)
+6i
+and Y (4)
+6ii stand for two linearly independent six-dimensional modular forms of
+weight 4. We use the same convention for other modular forms. Similarly, we construct the
+modular forms of weight 6 as
+Y (6)
+10
+0 (τ) =
+�
+Y (2)
+20 Y (4)
+20
+�
+10
+0
+,
+Y (6)
+11
+0 (τ) =
+�
+Y (2)
+11
+2 Y (4)
+10
+1
+�
+11
+0
+,
+Y (6)
+11
+2 (τ) =
+�
+Y (2)
+11
+2 Y (4)
+10
+0
+�
+11
+2
+,
+(92)
+Y (6)
+20 (τ) =
+�
+Y (2)
+20 Y (4)
+10
+0
+�
+20 ,
+Y (6)
+21 (τ) =
+�
+Y (2)
+20 Y (4)
+10
+1
+�
+21 ,
+Y (6)
+22 (τ) =
+�
+Y (2)
+11
+2 Y (4)
+20
+�
+22 ,
+(93)
+Y (6)
+30i(τ) =
+�
+Y (2)
+30 Y (4)
+10
+1
+�
+30 ,
+Y (6)
+30ii(τ) =
+�
+Y (2)
+30 Y (4)
+10
+0
+�
+30 ,
+Y (6)
+31 (τ) =
+�
+Y (2)
+11
+2 Y (4)
+30
+�
+31 ,
+(94)
+Y (6)
+6i (τ) =
+�
+Y (2)
+20 Y (4)
+31
+�
+6 ,
+Y (6)
+6ii (τ) =
+�
+Y (2)
+6 Y (4)
+10
+0
+�
+6 ,
+Y (6)
+6iii(τ) =
+�
+Y (2)
+30 Y (4)
+20
+�
+6 .
+(95)
+In Table 8 we summarize the modular forms of level 6 of even weights up to 6.
+Modular form Y (kY )
+r
+kY = 2
+Y (2)
+11
+2 , Y (2)
+20 , Y (2)
+30 , Y (2)
+6
+kY = 4
+Y (4)
+10
+0 , Y (4)
+10
+1 , Y (4)
+20 , Y (4)
+22 , Y (4)
+30 , Y (4)
+31 , Y (4)
+6i , Y (4)
+6ii
+kY = 6
+Y (6)
+10
+0 , Y (6)
+11
+0 , Y (6)
+11
+2 , Y (6)
+20 , Y (6)
+21 , Y (6)
+22 , Y (6)
+30i, Y (6)
+30ii, Y (6)
+31 , Y (6)
+6i , Y (6)
+6ii , Y (6)
+6iii
+Table 8: The modular forms of level 6 of even weights up to 6.
+Also we construct the singlet modular forms of weights 8, 10, 12 and 14 which we have used
+in our analysis. First, the singlet modular forms of weight 8 are given by
+Y (8)
+10
+0 =
+�
+Y (4)
+10
+0 Y (4)
+10
+0
+�
+10
+0
+,
+Y (8)
+10
+1 =
+�
+Y (4)
+10
+0 Y (4)
+10
+1
+�
+10
+1
+,
+Y (8)
+10
+2 =
+�
+Y (4)
+10
+1 Y (4)
+10
+1
+�
+10
+2
+,
+Y (8)
+11
+2 =
+�
+Y (4)
+20 Y (4)
+22
+�
+11
+2
+.
+(96)
+The singlet modular forms of weight 10 are given by
+Y (10)
+10
+0
+=
+�
+Y (4)
+10
+0 Y (6)
+10
+0
+�
+10
+0
+,
+Y (10)
+10
+1
+=
+�
+Y (4)
+10
+1 Y (6)
+10
+0
+�
+10
+1
+,
+Y (10)
+11
+0
+=
+�
+Y (4)
+10
+0 Y (6)
+11
+0
+�
+11
+0
+,
+(97)
+Y (10)
+11
+1
+=
+�
+Y (4)
+10
+1 Y (6)
+11
+0
+�
+11
+1
+,
+Y (10)
+11
+2
+=
+�
+Y (4)
+10
+0 Y (6)
+11
+2
+�
+11
+2
+.
+(98)
+22
+
+The singlet modular forms of weight 12 are given by
+Y (12)
+10
+0i =
+�
+Y (6)
+10
+0 Y (6)
+10
+0
+�
+10
+0
+,
+Y (12)
+10
+0ii =
+�
+Y (6)
+11
+0 Y (6)
+11
+0
+�
+10
+0
+,
+Y (12)
+10
+1
+=
+�
+Y (6)
+11
+2 Y (6)
+11
+2
+�
+10
+1
+,
+(99)
+Y (12)
+10
+2
+=
+�
+Y (6)
+11
+0 Y (6)
+11
+2
+�
+10
+2
+,
+Y (12)
+11
+0
+=
+�
+Y (6)
+10
+0 Y (6)
+11
+0
+�
+11
+0
+,
+Y (12)
+11
+2
+=
+�
+Y (6)
+10
+0 Y (6)
+11
+2
+�
+11
+2
+.
+(100)
+The singlet modular forms of weight 14 are given by
+Y (14)
+10
+0
+=
+�
+Y (6)
+10
+0 Y (8)
+10
+0
+�
+10
+0
+,
+Y (14)
+10
+1
+=
+�
+Y (6)
+10
+0 Y (8)
+10
+1
+�
+10
+1
+,
+Y (14)
+10
+2
+=
+�
+Y (6)
+10
+0 Y (8)
+10
+2
+�
+10
+2
+,
+(101)
+Y (14)
+11
+0
+=
+�
+Y (6)
+11
+0 Y (8)
+10
+0
+�
+11
+0
+,
+Y (14)
+11
+1
+=
+�
+Y (6)
+11
+0 Y (8)
+10
+1
+�
+11
+1
+,
+Y (14)
+11
+2i =
+�
+Y (6)
+11
+2 Y (8)
+10
+0
+�
+11
+2
+,
+(102)
+Y (14)
+11
+2ii =
+�
+Y (6)
+11
+0 Y (8)
+10
+2
+�
+11
+2
+.
+(103)
+In Table 9 we summarize the singlet modular forms of level 6 of weights 8, 10, 12 and 14.
+Modular form Y (kY )
+r
+kY = 8
+Y (8)
+10
+0 , Y (8)
+10
+1 , Y (8)
+10
+2 , Y (8)
+11
+2
+kY = 10
+Y (10)
+10
+0 , Y (10)
+10
+1 , Y (10)
+11
+0 , Y (10)
+11
+1 , Y (10)
+11
+2
+kY = 12
+Y (12)
+10
+0i , Y (12)
+10
+0ii, Y (12)
+10
+1 , Y (12)
+10
+2 , Y (12)
+11
+0 , Y (12)
+11
+2
+kY = 14
+Y (14)
+10
+0 , Y (14)
+10
+1 , Y (14)
+10
+2 , Y (14)
+11
+0 , Y (14)
+11
+1 , Y (14)
+11
+2i , Y (14)
+11
+2ii
+Table 9: The singlet modular forms of level 6 of weights 8, 10, 12 and 14.
+23
+
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diff --git a/2NE2T4oBgHgl3EQfNgYt/content/tmp_files/load_file.txt b/2NE2T4oBgHgl3EQfNgYt/content/tmp_files/load_file.txt
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@@ -0,0 +1,1653 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf,len=1652
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='03737v1  [hep-ph]  10 Jan 2023  EPHOU-23-001  Quark hierarchical structures in modular symmetric  flavor models at level 6  Shota Kikuchi, Tatsuo Kobayashi, Kaito Nasu,  Shohei Takada, and Hikaru Uchida  Department of Physics, Hokkaido University, Sapporo 060-0810, Japan  Abstract  We study modular symmetric quark flavor models without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Mass matrices are  written in terms of modular forms, and modular forms in the vicinity of the modular fixed  points become hierarchical depending on their residual charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Thus modular symmetric  flavor models in the vicinity of the modular fixed points have a possibility to describe  mass hierarchies without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Since describing quark hierarchies without fine-tuning  requires Zn residual symmetry with n ≥ 6, we focus on Γ6 modular symmetry in the  vicinity of the cusp τ = i∞ where Z6 residual symmetry remains.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We use only modular  forms belonging to singlet representations of Γ6 to make our analysis simple.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Consequently,  viable quark flavor models are obtained without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  1  Introduction  The origin of quark and lepton flavor structures such as hierarchical masses and mixing angles  is one of challenging issues in particle physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Indeed, many works were done in order to  solve the problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Among such works, modular symmetric flavor models are interesting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In  these flavor models, the quark and lepton mass matrices are written in terms of modular forms,  which are holomorphic functions of the modulus τ [1] 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' It is well known that the finite modular  groups ΓN for N = 2, 3, 4, 5 are isomorphic to the non-Abelian finite groups S3, A4, S4 and  A5, respectively [17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' This is interesting since the non-Abelian finite groups are long familiar  in flavor models for quarks and leptons [18–28].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Inspired by this point, the modular symmetric  lepton flavor models have been proposed in Γ2 ≃ S3 [29], Γ3 ≃ A4 [1], Γ4 ≃ S4 [30] and  Γ5 ≃ A5 [31, 32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In addition, modular symmetries at levels 6 [33] and 7 [34] were studied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Furthermore, modular forms of other groups were also studied [7,35–38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Using these various modular forms, the mass ratios and flavor mixing of quarks and leptons  have been discussed successfully in these years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Phenomenological studies have been developed  in many works and interesting results have been obtained [39–78].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' However, one needs to fine-  tune coefficients of modular forms in Yukawa couplings in order to describe the hierarchical  structure of fermion masses, in particular quark mass hierarchies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Describing the lepton flavors without fine-tuning on modular invariant models was proposed  in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [79].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Authors focused on the vicinity of three modular fixed points, τ = i, ω (=  e2πi/3) and i∞ where residual symmetries remain [42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The values of modular forms become  hierarchical as close to these modular fixed points due to approximate residual symmetries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Then, the hierarchy among values of the modular forms is determined by charges of residual  symmetries at the modular fixed points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' For instance the modular forms of Γ4 ≃ S4 with Z4  (T-transformation) charges 0, 1, 2 and 3 can take the sizes 1, ε, ε2 and ε3, respectively in the  vicinity of τ = i∞, where ε expresses the deviation from the modular fixed points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Indeed viable  lepton models on the double covering groups of ΓN, Γ′  3 ≃ A′  4, Γ′  4 ≃ S′  4 and Γ5 ≃ A′  5, were studied  in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [79].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' This is one successful way to generate hierarchical structures without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Nevertheless the realization of the quark flavor structure is not straightforward.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Experiments  show mass hierarchies of up sector quarks as mu/mt ∼ 10−5 and mc/mt ∼ 10−2-10−3 and ones  of down sector quarks as md/mb ∼ 10−3 and ms/mb ∼ 10−2 [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Suppose that ε = O(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Then, we could explain these mass ratios except mu/mt ∼ 10−5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' However, ε5 does not appear  in the framework of the finite modular group of level N less than 6 since the present residual  symmetries Z2, Z3 and ZN at τ = i, ω and i∞ do not possess the charge larger than 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Thus describing the quark flavor structure without fine-tuning requires the way generating  hierarchical mass ratios including ε5 = O(10−5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  One way is to relax the quark mass eigenvalues by tuning the values of coupling constants in  Yukawa couplings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [81], the quark flavor model with A4 modular symmetry was studied  and succeeded to generate both up and down sector quark mass hierarchies by adjusting one  1The modular flavor symmetry was also studied from the top-down approach such as string theory [2–16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  1  coupling constant ratio denoted by gu/gd to O(10).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, quark mass hierarchies originate  from following two origins,  (i) The vacuum expectation value (VEV) of the modulus τ (the deviation from the modular  fixed points),  (ii) The coupling constants in Yukawa couplings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Another way is to introduce the finite modular symmetry including Zn residual symmetry  with n ≥ 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In such models, the modular forms in the vicinity of the symmetric points can  take the sizes 1, ε, · · ·, εn−1 depending on their residual charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Hence, it may be possible  to generate mass hierarchies in both up and down sector quarks without fine-tuning using the  hierarchical values of the modular forms up to ε5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Note that in this way quark mass hierarchies  simply originate from (i) above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In this paper, we study the modular symmetric quark flavor  model with the finite modular group of level 6, Γ6 ≃ S3 × A4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The finite modular symmetry  Γ6 breaks into Z6 (T-transformation) residual symmetry at τ = i∞ and can generate the  hierarchical values of the modular forms up to ε5 in the vicinity of τ = i∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  This paper is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In section 2, we study generic aspects for the modular  symmetric quark flavor models being able to realize both up and down sector quark mass  hierarchies without fine-tuning along the lines proposed in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [79].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In section 3, we study quark  flavor models with the finite modular group Γ6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Section 4 is our conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We summarize  group theoretical aspects of Γ6 in appendix A and the modular forms of level 6 in appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  2  Hierarchical quark mass matrices without fine-tuning  In this section, we present modular symmetric quark flavor models without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We  start from the following assignment of modular weights to supermultiplets:  quark doublets Q = (Q1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Q2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Q3) are assigned into three-dimensional (reducible or irre-  ducible ) representation of a finite modular group with weight −kQ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  up sector quark singlets uR = (u1  R,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' u2  R,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' u3  R) are assigned into three-dimensional (reducible  or irreducible ) representation of a finite modular group with weight −ku,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  down sector quark singlets dR = (d1  R,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' d2  R,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' d3  R) are assigned into three-dimensional (re-  ducible or irreducible ) representation of a finite modular group with weight −kd,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  each of up and down sector Higgs fields Hu,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='d is assigned into one-dimensional representa-  tions of a finite modular group with weight −kHu,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Note that three-dimensional representations are constructed by combining singlets, doublets  and triplets of any finite modular groups.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The most general form of the superpotential relevant  2  to up sector quark masses is written as  Wu =  �  ri  \uf8ee  \uf8f0Y (kYu)  ri  �  Q1  Q2  Q3�  \uf8eb  \uf8ed  α11  ri  α12  ri  α13  ri  α21  ri  α22  ri  α23  ri  α31  ri  α32  ri  α33  ri  \uf8f6  \uf8f8  \uf8eb  \uf8ed  u1  R  u2  R  u3  R  \uf8f6  \uf8f8 Hu  \uf8f9  \uf8fb  1  ,  (1)  where Y (kYu)  ri  denotes the modular forms of irreducible representation ri for weight kYu = kQ +  ku + kHu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Some of coupling constants αij may be related each other when quark doublets Q  and/or up sector quark singlets uR belong to multiplets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Similarly the superpotential relevant  to down sector quark masses is written as  Wd =  �  ri  \uf8ee  \uf8f0Y  (kYd)  ri  �  Q1  Q2  Q3�  \uf8eb  \uf8ed  β11  ri  β12  ri  β13  ri  β21  ri  β22  ri  β23  ri  β31  ri  β32  ri  β33  ri  \uf8f6  \uf8f8  \uf8eb  \uf8ed  d1  R  d2  R  d3  R  \uf8f6  \uf8f8 Hd  \uf8f9  \uf8fb  1  ,  (2)  with kYd = kQ + kd + kHd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' They lead to the up and down sector quark mass matrices,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Mu and  Md,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  �  Q1  Q2  Q3�  Mu  \uf8eb  \uf8ed  u1  R  u2  R  u3  R  \uf8f6  \uf8f8 =  �  ri  \uf8ee  \uf8f0Y (kYu)  ri  �  Q1  Q2  Q3�  \uf8eb  \uf8ed  α11  ri  α12  ri  α13  ri  α21  ri  α22  ri  α23  ri  α31  ri  α32  ri  α33  ri  \uf8f6  \uf8f8  \uf8eb  \uf8ed  u1  R  u2  R  u3  R  \uf8f6  \uf8f8 ⟨Hu⟩  \uf8f9  \uf8fb  1  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (3)  �  Q1  Q2  Q3�  Md  \uf8eb  \uf8ed  d1  R  d2  R  d3  R  \uf8f6  \uf8f8 =  �  ri  \uf8ee  \uf8f0Y  (kYd)  ri  �  Q1  Q2  Q3�  \uf8eb  \uf8ed  β11  ri  β12  ri  β13  ri  β21  ri  β22  ri  β23  ri  β31  ri  β32  ri  β33  ri  \uf8f6  \uf8f8  \uf8eb  \uf8ed  d1  R  d2  R  d3  R  \uf8f6  \uf8f8 ⟨Hd⟩  \uf8f9  \uf8fb  1  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (4)  We expect that the coefficients αij and βij are of O(1), because we do not explain quark  mass hierarchies by using hierarchies of these coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In particular, we restrict all coupling  constants αij and βij to ±1 and study the realization of the orders of mass ratios and the  Cabibbo, Kobayashi, Maskawa (CKM) matrix elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Then free parameter is only the value  of the modulus τ (and the choices of +1 or −1 in coupling constants αij and βij).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (mu, mc, mt)/mt  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='26 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='38 × 10−3, 1)  (md, ns, mb)/mb  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='22 × 10−2, 1)  Table 1: Observed values of quark masses [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  In order to realize hierarchical quark masses as shown in Table 1 without fine-tuning, it is  necessary to generate hierarchies by values of the modular forms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Actually such hierarchical  values of the modular forms can be realized in a vicinity of three modular fixed points, τ = i,  ω and i∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' This can be understood as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As an example let us consider Zn symmetric  point and quark doublets Q, up sector quark singlets uR and up-type Higgs field Hu with the  following Zn residual charges,  Q : (1, n − 1, 0),  uR : (1, 0, 0),  Hu : 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (5)  3  Then the entities of the up sector quark mass matrix, Mij  u , must have the following Zn residual  charges to make Lagrangian modular invariant,  Mij  u :  \uf8eb  \uf8ed  n − 2  n − 1  n − 1  0  1  1  n − 1  0  0  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (6)  In the vicinity of Zn symmetric point, the modular forms with Zn residual charge q, f(τ), can  be expanded by the deviation from the symmetric point to the power of q [79]:  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' τ ∼ i: f(τ) ∼ εq, ε ≡ τ−i  τ+i,  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' τ ∼ ω: f(τ) ∼ εq, ε ≡  τ−ω  τ−ω2,  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' τ ∼ i∞: f(τ) ∼ εq, ε ≡ e−2πImτ/N (N is a level of the finite modular group).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Thus the above up sector quark mass matrix can be evaluated as  Mij  u ∼  \uf8eb  \uf8ed  εn−2  εn−1  εn−1  1  ε  ε  εn−1  1  1  \uf8f6  \uf8f8 ,  (7)  in the vicinity of Zn symmetric point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Similarly, for the down sector quark mass matrix as  well as lepton mass matrices, the modular forms take hierarchical values depending on their  residual charges and lead to hierarchical mass matrices as close to the modular fixed points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  In Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [79], lepton flavor models without fine-tuning around the vicinity of the modular fixed  points was studied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  On the other hand, it is difficult to realize quark mass hierarchies by the values of the  modular forms in the vicinity of τ = i and ω.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' To realize both up and down sector quark mass  hierarchies in Table 1 simultaneously, we may need ε to the fifth power, when ε = O(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Hence  we need five different residual charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' This requirement excludes the vicinity of τ = i and ω  since they correspond to Z2 and Z3 symmetries, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In other words, such hierarchical  masses can be realized in the vicinity of the cusp τ = i∞ with ZN charge for N ≥ 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Let us discuss the candidates of the modular symmetry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  As mentioned above the level  of the modular symmetry must be lager than 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Here we focus on the levels 6 and 7, that  is, Γ6 ≃ S3 × A4 and Γ7 ≃ PSL(2, Z7) as the candidates of the modular symmetry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As the  irreducible representations less than four dimension, Γ7 ≃ PSL(2, Z7) has only one singlet 1  and two triplets 3 and ¯3 [34];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' this variety of irreducible representations may not be enough  to find the models being able to realize both up and down sector quark masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In contrast,  Γ6 ≃ S3 × A4 has six singlets, 10  0, 10  1, 10  2, 11  0, 11  1 and 11  2, three doublets, 20, 21 and 22, and two  triplets, 30 and 31 [33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' They would be sufficient to find realistic models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In the following, we  consider the models with Γ6 modular symmetry and realize quark flavors without fine-tuning  in the vicinity of τ = i∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  4  3  The models with Γ6 modular symmetry  Here we study the models with Γ6 modular symmetry and realize the quark flavor structure  without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As we have mentioned in the previous section, we restrict all couplings αij  and βij to ±1 in quark mass matrices to avoid fine-tuning by them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We study the realization  of the orders of mass ratios and mixing angles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We use only the modulus τ (and the choices of  +1 or -1 in αij and βij) as a free parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  In Γ6 modular symmetry, ε to the power up to 5 can appear in mass matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Indeed six  Γ6 singlets with six different T-charges correspond to different powers of ε in the vicinity of  τ = i∞ as shown in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  singlet  10  0  11  2  10  1  11  0  10  2  11  1  T-charge  0  1  2  3  4  5  order  1  ε  ε2  ε3  ε4  ε5  Table 2: T-charges of six Γ6 singlets and their orders in the vicinity of τ = i∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  To realize the quark flavor structure,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' let us consider the following four types of mass matrices,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Type I:  Mu ∝  \uf8eb  \uf8ed  ε5  ε3−a+b  εb  ±ε5+a−b  ±ε3  ±εa  ±ε5−b  ±ε3−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md ∝  \uf8eb  \uf8ed  ε3  ε2−a+b  εb  ±ε3+a−b  ±ε2  ±εa  ±ε3−b  ±ε2−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (8)  Type II:  Mu ∝  \uf8eb  \uf8ed  ε5  ε3−a+b  εb  ±ε5+a−b  ±ε3  ±εa  ±ε5−b  ±ε3−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md ∝  \uf8eb  \uf8ed  ε4  ε2−a+b  εb  ±ε4+a−b  ±ε2  ±εa  ±ε4−b  ±ε2−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (9)  Type III:  Mu ∝  \uf8eb  \uf8ed  ε5  ε2−a+b  εb  ±ε5+a−b  ±ε2  ±εa  ±ε5−b  ±ε2−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md ∝  \uf8eb  \uf8ed  ε3  ε2−a+b  εb  ±ε3+a−b  ±ε2  ±εa  ±ε3−b  ±ε2−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (10)  Type IV:  Mu ∝  \uf8eb  \uf8ed  ε5  ε2−a+b  εb  ±ε5+a−b  ±ε2  ±εa  ±ε5−b  ±ε2−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md ∝  \uf8eb  \uf8ed  ε4  ε2−a+b  εb  ±ε4+a−b  ±ε2  ±εa  ±ε4−b  ±ε2−a  ±1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (11)  where ± corresponds any possible combinations of signs and a,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' b ∈ {0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 5}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Note that  it is always possible to fix the signs of (1,1), (1,2) and (1,3) components to +1 by the basis  transformation for right-handed quarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We set powers of ε on diagonal components in up and  down sector quark mass matrices to (5,3,0) and (3,2,0) for type I, (5,3,0) and (4,2,0) for type  II, (5,2,0) and (3,2,0) for type III and (5,2,0) and (4,2,0) for type IV in order to realize their  hierarchical masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Here, we use only six Γ6 singlets, 10  0, 10  1, 10  2, 11  0, 11  1 and 11  2, as irreducible  representations to make our analysis simple.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Note that again powers of ε in mass matrices are  determined by Z6 charges of entities of mass matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Thus mass matrices of each type can be  5  led by the following assignments,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Type I :  Q = (1b mod 2  b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 1a mod 2  a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' uR = (15−b mod 2  5−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 13−a mod 2  3−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' dR = (13−b mod 2  3−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 12−a mod 2  2−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (12)  Type II :  Q = (1b mod 2  b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 1a mod 2  a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' uR = (15−b mod 2  5−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 13−a mod 2  3−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' dR = (14−b mod 2  4−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 12−a mod 2  2−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (13)  Type III :  Q = (1b mod 2  b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 1a mod 2  a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' uR = (15−b mod 2  5−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 12−a mod 2  2−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' dR = (13−b mod 2  3−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 12−a mod 2  2−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (14)  Type IV :  Q = (1b mod 2  b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 1a mod 2  a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' uR = (15−b mod 2  5−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 12−a mod 2  2−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' dR = (14−b mod 2  4−b mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 12−a mod 2  2−a mod 3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (15)  On the other hand, it is not always true that mass matrices in four types are definitely realized  by the above assignments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' It depends on weights of the Yukawa couplings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' All of the singlet  modular forms of Γ6 with certain Z6 charges do not exist for weights less than 14 as shown in  appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' For instance, the modular forms of weight 12 belong to 11  1 do not exist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Yukawa  couplings of the weights less than 14 can lead to mass matrices with some zeros due to this  shortage of the modular forms on low weights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We study the case of Yukawa couplings of the  weight 14 in subsection 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1 and one of the weights less than 14 in subsection 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1  Weight 14  First of all, we study the models with Yukawa couplings of weight 14 to avoid zero textures in  mass matrices of four types.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We choose τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i as a benchmark point of the modulus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' At  weight 14, seven singlet modular forms, Y (14)  10  0 , Y (14)  11  2i , Y (14)  10  1 , Y (14)  11  0 , Y (14)  10  2 , Y (14)  11  1  and Y (14)  11  2ii, exist  and they are approximated by ε as  Y (14)  10  0 /Y (14)  10  0  = 1 → 1,  Y (14)  11  2i /Y (14)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='172 → ε,  (16)  Y (14)  10  1 /Y (14)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208 → ε2,  Y (14)  11  0 /Y (14)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358 → ε3,  (17)  Y (14)  10  2 /Y (14)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435 → ε4,  Y (14)  11  1 /Y (14)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746 → ε5,  (18)  Y (14)  11  2ii/Y (14)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00000156 → ε7,  (19)  at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Note that Y (14)  11  2ii ∼ ε7 originates from Y (6)  11  0 Y (8)  10  2 ∼ ε3 · ε4 while Y (14)  11  2i ∼ ε originates  from Y (6)  11  2 Y (8)  10  0 ∼ ε · 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' εn for n > 5 can appear when the different modular forms of the same  irreducible representations exist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In what follows, we ignore Y (14)  11  2ii because it belongs to the  same representation as Y (14)  11  2i and Y (14)  11  2i >> Y (14)  11  2ii.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  6  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1  Type I: (5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0) and (3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0)  The mass matrices of type I are given by  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ed  α11Y (14)  11  1  α12Y (14)  13+a−b mod 2  3+a−b mod 3  α13Y (14)  16−b mod 2  6−b mod 3  α21Y (14)  11−a+b mod 2  1−a+b mod 3  α22Y (14)  11  0  α23Y (14)  16−a mod 2  6−a mod 3  α31Y (14)  11+b mod 2  1+b mod 3  α32Y (14)  13+a mod 2  3+a mod 3  α33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (20)  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ed  β11Y (14)  11  0  β12Y (14)  14+a−b mod 2  4+a−b mod 3  β13Y (14)  16−b mod 2  6−b mod 3  β21Y (14)  13−a+b mod 2  3−a+b mod 3  β22Y (14)  10  1  β23Y (14)  16−a mod 2  6−a mod 3  β31Y (14)  13+b mod 2  3+b mod 3  β32Y (14)  14+a mod 2  4+a mod 3  β33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (21)  where αij and βij are coupling constants which we restrict to ±1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The hierarchical mass matrices  in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (8) can be obtained by choosing +1 or −1 appropriately in αij and βij.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, we  find best-fit mass matrices at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i,  Mu/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  11  1  Y (14)  10  2  Y (14)  11  0  Y (14)  10  2  Y (14)  11  0  Y (14)  10  1  −Y (14)  10  1  −Y (14)  11  2i  Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='172  1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε5  ε4  ε3  ε4  ε3  ε2  −ε2  −ε  1  \uf8f6  \uf8f8 ,  (22)  Md/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  11  0  Y (14)  11  0  Y (14)  11  0  Y (14)  10  1  −Y (14)  10  1  −Y (14)  10  1  −Y (14)  10  0  Y (14)  10  0  −Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −1  1  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε3  ε3  ε3  ε2  −ε2  −ε2  −1  1  −1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (23)  These mass matrices correspond to a = 2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' b = 3 and can be realized by  Q = (11  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  uR = (10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  dR = (10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (24)  and their mass matrices are written by,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  α11Y (14)  11  1  α12Y (14)  10  2  α13Y (14)  11  0  α21Y (14)  10  2  α22Y (14)  11  0  α23Y (14)  10  1  α31Y (14)  10  1  α32Y (14)  11  2i  α33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  β11Y (14)  11  0  β12Y (14)  11  0  β13Y (14)  11  0  β21Y (14)  10  1  β22Y (14)  10  1  β23Y (14)  10  1  β31Y (14)  10  0  β32Y (14)  10  0  β33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (25)  7  with the following choises of +1 or −1 in coupling constants,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  α11  α12  α13  α21  α22  α23  α31  α32  α33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  1  1  −1  −1  1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  β11  β12  β13  β21  β22  β23  β31  β32  β33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  −1  −1  −1  1  −1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (26)  They lead to the following quark mass ratios,  (mu, mc, mt)/mt = (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='11 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='07 × 10−3, 1),  (27)  (md, ms, mb)/mb = (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='91 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='97 × 10−2, 1),  (28)  and the absolute values of the CKM matrix elements,  |VCKM| =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='231  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000681  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='231  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0270  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00690  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0261  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (29)  Results are shown in Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Our purpose is to derive quark masses and mixing angles  without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Thus, we have fixed αij, βij = ±1 to make our point clear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' If we vary  αij, βij = O(1) without fixing αij, βij = ±1, we can obtain more realistic values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Of course, we  have ambiguity in normalization of modular forms, although we expect naturally that normal-  ization factors would not lead a large hierarchy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Our values appear at a high energy scale such  as the GUT scale.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Renormalization group effects change values by some factors, although such  radiative corrections may be realized by varying αij, βij = O(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Obtained values  Observed values  (mu, mc, mt)/mt  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='11 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='07 × 10−3, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='26 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='38 × 10−3, 1)  (md, ms, mb)/mb  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='91 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='97 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='22 × 10−2, 1)  |VCKM|  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='231  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000681  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='231  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0270  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='0261  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f7  \uf8f7  \uf8f8  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00361  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='226  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='0405  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00854  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0398  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='999  \uf8f6  \uf8f7  \uf8f7  \uf8f8  Table 3: The mass ratios of the quarks and the absolute values of the CKM matrix elements  at the benchmark point τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i in the best-fit model by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (24) and (26) of type I with  Yukawa couplings of weight 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Observed values are shown in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  8  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2  Type II: (5,3,0) and (4,2,0)  The mass matrices of type II are given by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (20) and  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ed  β11Y (14)  10  2  β12Y (14)  14+a−b mod 2  4+a−b mod 3  β13Y (14)  16−b mod 2  6−b mod 3  β21Y (14)  12−a+b mod 2  2−a+b mod 3  β22Y (14)  10  1  β23Y (14)  16−a mod 2  6−a mod 3  β31Y (14)  12+b mod 2  2+b mod 3  β32Y (14)  14+a mod 2  4+a mod 3  β33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (30)  The hierarchical mass matrices in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (9) can be obtained by choosing +1 or −1 appropriately  in αij and βij.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, we find best-fit mass matrices at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i,  Mu/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  11  1  Y (14)  10  2  Y (14)  11  0  Y (14)  10  2  Y (14)  11  0  −Y (14)  10  1  −Y (14)  10  1  −Y (14)  11  2i  −Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='172  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε5  ε4  ε3  ε4  ε3  −ε2  −ε2  −ε  −1  \uf8f6  \uf8f8 ,  (31)  Md/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  10  2  Y (14)  11  0  Y (14)  11  0  −Y (14)  11  0  Y (14)  10  1  Y (14)  10  1  Y (14)  11  2i  Y (14)  10  0  −Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='172  1  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε4  ε3  ε3  −ε3  ε2  ε2  ε  1  −1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (32)  These mass matrices correspond to a = 2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' b = 3 and can be realized by  Q = (11  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  uR = (10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  dR = (11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (33)  and their mass matrices are written by,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  α11Y (14)  11  1  α12Y (14)  10  2  α13Y (14)  11  0  α21Y (14)  10  2  α22Y (14)  11  0  α23Y (14)  10  1  α31Y (14)  10  1  α32Y (14)  11  2i  α33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  β11Y (14)  10  2  β12Y (14)  11  0  β13Y (14)  11  0  β21Y (14)  11  0  β22Y (14)  10  1  β23Y (14)  10  1  β31Y (14)  11  2i  β32Y (14)  10  0  β33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (34)  with the following choises of +1 or −1 in coupling constants,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  α11  α12  α13  α21  α22  α23  α31  α32  α33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  1  −1  −1  −1  −1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  β11  β12  β13  β21  β22  β23  β31  β32  β33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  −1  1  1  1  1  −1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (35)  9  They lead to the following quark mass ratios,  (mu, mc, mt)/mt = (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='14 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00 × 10−3, 1),  (36)  (md, ms, mb)/mb = (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='16 × 10−4, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='11 × 10−2, 1),  (37)  and the absolute values of the CKM matrix elements,  |VCKM| =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='982  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='190  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00309  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='190  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='982  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0200  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00683  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0191  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (38)  Results are shown in Table 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Obtained values  Observed values  (mu, mc, mt)/mt  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='14 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00 × 10−3, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='26 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='38 × 10−3, 1)  (md, ms, mb)/mb  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='16 × 10−4, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='11 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='22 × 10−2, 1)  |VCKM|  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='982  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='190  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00309  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='190  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='982  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0200  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00683  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0191  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f7  \uf8f7  \uf8f8  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='226  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0405  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00854  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0398  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='999  \uf8f6  \uf8f7  \uf8f7  \uf8f8  Table 4: The mass ratios of the quarks and the absolute values of the CKM matrix elements  at the benchmark point τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i in the best-fit model by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (33) and (35) of type II with  Yukawa couplings of weight 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Observed values are shown in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='3  Type III: (5,2,0) and (3,2,0)  The mass matrices of type III are given by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (21) and  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ed  α11Y (14)  11  1  α12Y (14)  14+a−b mod 2  4+a−b mod 3  α13Y (14)  16−b mod 2  6−b mod 3  α21Y (14)  11−a+b mod 2  1−a+b mod 3  α22Y (14)  10  1  α23Y (14)  16−a mod 2  6−a mod 3  α31Y (14)  11+b mod 2  1+b mod 3  α32Y (14)  14+a mod 2  4+a mod 3  α33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (39)  10  The hierarchical mass matrices in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (10) can be obtained by choosing +1 or −1 appropriately  in αij and βij.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, we find best-fit mass matrices at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i,  Mu/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  11  1  Y (14)  11  0  Y (14)  11  0  Y (14)  10  2  −Y (14)  10  1  −Y (14)  10  1  Y (14)  10  1  Y (14)  10  0  −Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  1  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε5  ε3  ε3  ε4  −ε2  −ε2  ε2  1  −1  \uf8f6  \uf8f8 ,  (40)  Md/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  11  0  Y (14)  11  0  Y (14)  11  0  Y (14)  10  1  Y (14)  10  1  −Y (14)  10  1  Y (14)  10  0  −Y (14)  10  0  Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  1  −1  1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε3  ε3  ε3  ε2  ε2  −ε2  1  −1  1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (41)  These mass matrices correspond to a = 2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' b = 3 and can be realized by  Q = (11  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  uR = (10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  dR = (10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (42)  and their mass matrices are written by,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  α11Y (14)  11  1  α12Y (14)  11  0  α13Y (14)  11  0  α21Y (14)  10  2  α22Y (14)  10  1  α23Y (14)  10  1  α31Y (14)  10  1  α32Y (14)  10  0  α33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  β11Y (14)  11  0  β12Y (14)  11  0  β13Y (14)  11  0  β21Y (14)  10  1  β22Y (14)  10  1  β23Y (14)  10  1  β31Y (14)  10  0  β32Y (14)  10  0  β33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (43)  with the following choises of +1 or −1 in coupling constants,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  α11  α12  α13  α21  α22  α23  α31  α32  α33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  −1  −1  1  1  −1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  β11  β12  β13  β21  β22  β23  β31  β32  β33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  1  −1  1  −1  1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (44)  They lead to the following quark mass ratios,  (mu, mc, mt)/mt = (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='04 × 10−4, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−2, 1),  (45)  (md, ms, mb)/mb = (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='91 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='97 × 10−2, 1),  (46)  and the absolute values of the CKM matrix elements,  |VCKM| =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='967  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='255  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00000171  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='255  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='967  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00706  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00180  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00682  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (47)  11  Results are shown in Table 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Obtained values  Observed values  (mu, mc, mt)/mt  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='04 × 10−4, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='26 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='38 × 10−3, 1)  (md, ms, mb)/mb  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='91 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='97 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='22 × 10−2, 1)  |VCKM|  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='967  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='255  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00000171  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='255  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='967  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00706  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00180  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00682  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f7  \uf8f7  \uf8f8  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00361  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='226  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0405  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00854  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0398  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='999  \uf8f6  \uf8f7  \uf8f7  \uf8f8  Table 5: The mass ratios of the quarks and the absolute values of the CKM matrix elements  at the benchmark point τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i in the best-fit model by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (42) and (44) of type III with  Yukawa couplings of weight 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Observed values are shown in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='4  Type IV: (5,2,0) and (4,2,0)  The mass matrices of type IV are given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (39) and (30).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The hierarchical mass matrices  in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (11) can be obtained by choosing +1 or −1 appropriately in αij and βij.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, we  find best-fit mass matrices at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i,  Mu/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  11  1  Y (14)  11  0  Y (14)  10  0  Y (14)  10  2  Y (14)  10  1  Y (14)  11  1  Y (14)  11  1  −Y (14)  11  0  −Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε5  ε3  1  ε4  ε2  ε5  ε5  −ε3  −1  \uf8f6  \uf8f8 ,  (48)  Md/Y (14)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (14)  10  2  Y (14)  11  0  Y (14)  10  0  Y (14)  11  0  −Y (14)  10  1  −Y (14)  11  1  Y (14)  10  2  Y (14)  11  0  −Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (14)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0208  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000746  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000435  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00358  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε4  ε3  1  ε3  −ε2  −ε5  ε4  ε3  −1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (49)  These mass matrices correspond to a = 5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' b = 0 and can be realized by  Q = (10  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  uR = (11  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  dR = (10  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (50)  12  and their mass matrices are written by,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  α11Y (14)  11  1  α12Y (14)  11  0  α13Y (14)  10  0  α21Y (14)  10  2  α22Y (14)  10  1  α23Y (14)  11  1  α31Y (14)  11  1  α32Y (14)  11  0  α33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  β11Y (14)  10  2  β12Y (14)  11  0  β13Y (14)  10  0  β21Y (14)  11  0  β22Y (14)  10  1  β23Y (14)  11  1  β31Y (14)  10  2  β32Y (14)  11  0  β33Y (14)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (51)  with the following choises of +1 or −1 in coupling constants,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  α11  α12  α13  α21  α22  α23  α31  α32  α33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  1  1  1  −1  −1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  β11  β12  β13  β21  β22  β23  β31  β32  β33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  1  −1  −1  1  1  −1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (52)  They lead to the following quark mass ratios,  (mu, mc, mt)/mt = (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='46 × 10−5, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='47 × 10−2, 1),  (53)  (md, ms, mb)/mb = (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='01 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='54 × 10−2, 1),  (54)  and the absolute values of the CKM matrix elements,  |VCKM| =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='000154  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (55)  Results are shown in Table 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Obtained values  Observed values  (mu, mc, mt)/mt  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='46 × 10−5, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='47 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='26 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='38 × 10−3, 1)  (md, ms, mb)/mb  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='01 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='54 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='22 × 10−2, 1)  |VCKM|  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='226  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000158  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000358  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000154  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f7  \uf8f7  \uf8f8  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00361  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='226  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0405  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00854  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0398  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='999  \uf8f6  \uf8f7  \uf8f7  \uf8f8  Table 6: The mass ratios of the quarks and the absolute values of the CKM matrix elements  at the benchmark point τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i in the best-fit model by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (50) and (52) of type IV with  Yukawa couplings of weight 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Observed values are shown in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2  Weights less than 14  Next we study the models with Yukawa couplings of weights less than 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In this case, some  of entities in mass matrices vanish because there do not exist modular forms of proper weights  13  and representations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As an example, let us consider the case that Yukawa couplings for the up  sector have the weight 8 and ones for the down sector have the weight 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We choose τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='7i  as a benchmark point of the modulus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' At weight 8, four singlet modular forms, Y (8)  10  0 , Y (8)  11  2 , Y (8)  10  1  and Y (8)  10  2 , exist and they are approximated by ε as  Y (8)  10  0 /Y (8)  10  0 = 1 → 1,  Y (8)  11  2 /Y (8)  10  0 = −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0719 → ε,  (56)  Y (8)  10  1 /Y (8)  10  0 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732 → ε2,  Y (8)  10  2 /Y (8)  10  0 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000535 → ε4,  (57)  at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='7i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' At weight 10, five singlet modular forms, Y (10)  10  0 , Y (10)  11  2 , Y (10)  10  1 , Y (10)  11  0  and Y (10)  11  1 , exist  and they are approximated by ε as  Y (10)  10  0 /Y (10)  10  0  = 1 → 1,  Y (10)  11  2 /Y (10)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='102 → ε,  (58)  Y (10)  10  1 /Y (10)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732 → ε2,  Y (10)  11  0 /Y (10)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000744 → ε3,  (59)  Y (10)  11  1 /Y (10)  10  0  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00000544 → ε5,  (60)  at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='7i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, we find the following best-fit mass matrices of type III,  Mu/Y (8)  10  0 =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0  0  Y (8)  10  1  Y (8)  10  2  Y (8)  10  1  Y (8)  11  2  0  −Y (8)  11  2  −Y (8)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (8)  10  0 =  \uf8eb  \uf8ed  0  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0000535  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0719  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0719  −1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  0  0  ε2  ε4  ε2  −ε  0  ε  −1  \uf8f6  \uf8f8 ,  (61)  Md/Y (10)  10  0  =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  Y (10)  11  0  Y (10)  11  0  Y (10)  10  1  −Y (10)  10  1  −Y (10)  10  1  Y (10)  11  2  Y (10)  11  2  −Y (10)  11  2  Y (10)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 /Y (10)  10  0  =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000744  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='000744  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00732  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='102  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='102  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='102  1  \uf8f6  \uf8f8  ∼  \uf8eb  \uf8ed  ε3  ε3  ε2  −ε2  −ε2  ε  ε  −ε  1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (62)  These mass matrices correspond to a = 1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' b = 2 and can be realized by  Q = (10  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  uR = (11  0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  dR = (11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 11  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 10  0),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (63)  and their mass matrices,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Mu =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0  0  α13Y (8)  10  1  α21Y (8)  10  2  α22Y (8)  10  1  α23Y (8)  11  2  0  α32Y (8)  11  2  α33Y (8)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Md =  \uf8eb  \uf8ec  \uf8ec  \uf8ed  β11Y (10)  11  0  β12Y (10)  11  0  β13Y (10)  10  1  β21Y (10)  10  1  β22Y (10)  10  1  β23Y (10)  11  2  β31Y (10)  11  2  β32Y (10)  11  2  β33Y (10)  10  0  \uf8f6  \uf8f7  \uf8f7  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (64)  14  with the following choises of +1 or −1 in coupling constants,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed α13  α21  α22  α23 α32  α33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed 1  1  1  1 −1  −1  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  \uf8eb  \uf8ed  β11  β12  β13  β21  β22  β23  β31  β32  β33  \uf8f6  \uf8f8 =  \uf8eb  \uf8ed  1  1  1  −1  −1  1  1  −1  1  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (65)  They lead to the following up quark and down quark mass ratios,  (mu, mc, mt)/mt = (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='27 × 10−5, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='18 × 10−3, 1),  (66)  (md, ms, mb)/mb = (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='44 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='74 × 10−2, 1),  (67)  and the absolute values of the CKM matrix elements,  |VCKM| =  \uf8eb  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00741  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0300  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0140  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0276  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (68)  Results are shown in Table 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Thus it is also possible to realize a realistic quark flavor structure  in the models with Yukawa couplings of weights less than 14 despite some zeros in mass matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Here we studied the case that Yukawa couplings for the up sector have weight 8 and ones for  the down sector have weight 10 but other cases may be available for realization of the quark  flavor structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Obtained values  Observed values  (mu, mc, mt)/mt  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='27 × 10−5, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='18 × 10−3, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='26 × 10−5, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='38 × 10−3, 1)  (md, ms, mb)/mb  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='44 × 10−3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='74 × 10−2, 1)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='12 × 10−3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='22 × 10−2, 1)  |VCKM|  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00741  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0300  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0140  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0276  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00  \uf8f6  \uf8f7  \uf8f7  \uf8f8  \uf8eb  \uf8ec  \uf8ec  \uf8ed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='974  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00361  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='226  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='973  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0405  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='00854  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='0398  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='999  \uf8f6  \uf8f7  \uf8f7  \uf8f8  Table 7: The mass ratios of the quarks and the absolute values of the CKM matrix elements at  the benchmark point τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='7i in the best-fit model by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (63) and (65) of type III with up  sector Yukawa couplings of weight 8 and down sector Yukawa couplings of weight 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Observed  values are shown in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='3  Comment on the origin of Γ6 modular symmetry  Here we comment on a plausible origin of Γ6 modular symmetry of the theories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' For example,  some modular forms are derived from the torus compactification T 2  1 ×T 2  2 ×T 2  3 of the low-energy  effective theory of the superstring theory with magnetic flux background [6–11].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The group Γ6  15  may originate from one of T 2  i , while the others T 2  j lead to a trivial symmetry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Alternatively,  since Γ6 ≃ S3 × A4 ≃ Γ2 × Γ3, it may be expected that Γ2 ≃ S3 originates from one torus T 2  1  and Γ3 ≃ A4 originates from another torus T 2  2 with the moduli stabilization τ1 = τ2 ≡ τ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Then  T 2  3 contributes to the group symmetry trivially.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  4  Conclusion  We have discussed the possibility to describe mass hierarchies of both up and down sector quarks  as well as mixing angles without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Describing the quark flavor structure requires Zn  residual symmetry with n ≥ 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We have studied the modular symmetric quark flavor models  of Γ6 ≃ S3 × A4 in the vicinity of the cusp τ = i∞ where Z6 residual symmetry remains.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Then  the values of the modular forms become hierarchical as close to the cusp depending on their Z6  residual charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  In order to obtain viable models, we consider four types of quark mass matrices;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' the diagonal  components in up and down sector quark mass matrices are written by ε with the powers of  (5, 3, 0) and (3, 2, 0) respectively for type I, (5, 3, 0) and (4, 2, 0) for type II, (5, 2, 0) and (3, 2, 0)  for type III, and (5, 2, 0) and (4, 2, 0) for type IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The powers of non-diagonal components in up  and down sector quark mass matrices have been treated as model depending values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' When we  assign the irreducible representations into quarks and Higgs fields, powers of ε in mass matrix  components are determined by residual charges of mass matrix components.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' For simplicity, we  have used only six singlets 10  0, 10  1, 10  2, 11  0, 11  1 and 11  2 as the irreducible representations of Γ6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  In addition, we have restricted the values of the coupling constants to ±1 to avoid fine-tuning  by them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Firstly, we have investigated the case that up and down sector Yukawa couplings have weight  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In such cases, mass matrices have no zeros, that is, all of their components are written in  terms of the modular forms for Γ6 of weight 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Consequently, we have obtained viable models  at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='2i for each type without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Second, we have shown the viable model in the case that Yukawa couplings of the up sector  have weight 8 and ones of the down sector have weight 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In this case some components of  mass matrices can become zero because there do not exist modular forms of proper weights  and representations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As a result, we have obtained the viable model at τ = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='7i despite three  zeros in the up quark mass matrix, Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' (61).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Thus, the modular symmetric quark flavor models based on Γ6 in the vicinity of the cusp τ =  i∞ lead to successful quark mass matrices without fine-tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' As we have commented in the  end of previous section, Γ6 ≃ S3 × A4 ≃ Γ2 × Γ3 may originate from the torus compactification  T 2  1 ×T 2  2 ×T 2  3 of the low-energy effective theory of superstring theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Motivated this point, the  modular flavor models based on the direct product of finite modular groups, ΓN1 × ΓN2 × ΓN3,  may be interesting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Also we can extend our analysis to the lepton sector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We will study them  in the near future.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  16  In our models, the important parameter is the modulus τ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' It must be stabilized such that  the proper mass hierarchies are realized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We would study such modulus stabilization elsewhere2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Acknowledgement  This work was supported by JSPS KAKENHI Grant Numbers JP22J10172 (SK) and JP20J20388  (HU), and JST SPRING Grant Number JPMJSP2119(KN).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Appendix  A  Tensor product of Γ6 group  Here, we give a review on group theoretical aspects of Γ6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The generators of Γ6 are denoted by  S and T, and they satisfy the following algebraic relations:  S2 = (ST)3 = T 6 = ST 2ST 3ST 4ST 3 = 1,  S2T = TS2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (69)  In Γ6 group, there are 12 irreducible representations, six singlets 10  0, 10  1, 10  2, 11  0, 11  1 and 11  2,  three doublets 20, 21 and 22, two triplets 30 and 31 and one six-dimensional representation 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Each irreducible representation is given by  1r  k : S = (−1)r,  T = (−1)rωk,  (70)  2k : S = 1  2  �−1  √  3  √  3  1  �  ,  T = ωk  �1  0  0  −1  �  ,  (71)  3r : (−1)ra3,  (−1)rb3,  (72)  6 : 1  2  � −a3  √  3a3  √  3a3  a3  �  ,  T =  �b3  0  0  −b3  �  ,  (73)  where r = 0, 1, k = 0, 1, 2 and  a3 = 1  3  \uf8eb  \uf8ed  −1  2  2  2  −1  2  2  2  −1  \uf8f6  \uf8f8 ,  b3 =  \uf8eb  \uf8ed  1  0  0  0  ω  0  0  0  ω2  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (74)  In this basis,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' the Kronecker products between irreducible representations are:  1r  i ⊗ 1s  j = 1t  m,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  1r  i ⊗ 2j = 2m,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  1r  i ⊗ 3s = 3t,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  1r  i ⊗ 6 = 6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (75)  2i ⊗ 2j = 10  m ⊕ 11  m ⊕ 2m,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  2i ⊗ 3r = 6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  2i ⊗ 6 = 30 ⊕ 31 ⊕ 6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (76)  3r ⊗ 3s = 1t  0 ⊕ 1t  1 ⊕ 1t  2 ⊕ 3t  1 ⊕ 3t  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  3r ⊗ 6 = 20 ⊕ 21 ⊕ 22 ⊕ 6 ⊕ 6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (77)  6 ⊗ 6 = 10  0 ⊕ 10  1 ⊕ 10  2 ⊕ 11  0 ⊕ 11  1 ⊕ 11  2 ⊕ 20 ⊕ 21 ⊕ 22 ⊕ 30 ⊕ 30 ⊕ 31 ⊕ 31 ⊕ 6 ⊕ 6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (78)  2See for modulus stabilization in modular flavor symmetric models Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [82–86] .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  17  where i, j = 0, 1, 2, r, s = 0, 1, m = i + j (mod 3) and t = r + s (mod 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' In the following, we  show the Clebsch-Gordon (CG) coefficients of these products.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (α1)1r  i ⊗  �β1  β2  �  2j  = α1P r  2  �β1  β2  �  2m  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (α1)1r  i ⊗  \uf8eb  \uf8ed  β1  β2  β3  \uf8f6  \uf8f8  3s  = α1P i  3  \uf8eb  \uf8ed  β1  β2  β3  \uf8f6  \uf8f8  3t  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (α1)1r  i ⊗  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ed  β1  β2  β3  β4  β5  β6  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f8  6  = α1P6(r,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' i)  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ed  β1  β2  β3  β4  β5  β6  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f8  6  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  �α1  α2  �  2i  ⊗  �β1  β2  �  2j  = 1  √  2  (α1β1 + α2β2)10m ⊕ 1  √  2  (α1β2 − α2β1)11m ⊕ 1  √  2  � α1β1 − α2β2  −α1β2 − α2β1  �  2m  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  �α1  α2  �  2i  ⊗  \uf8eb  \uf8ed  β1  β2  β3  \uf8f6  \uf8f8  3r  = P6(r,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' i)  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ed  α1β1  α1β2  α1β3  α2β1  α2β2  α2β3  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f8  6  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  �α1  α2  �  2i  ⊗  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ed  β1  β2  β3  β4  β5  β6  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f8  6  = P i  3  √  2  \uf8eb  \uf8ed  α1β1 + α2β4  α1β2 + α2β5  α1β3 + α2β6  \uf8f6  \uf8f8  30  ⊕ P i  3  √  2  \uf8eb  \uf8ed  α1β4 − α2β1  α1β5 − α2β2  α1β6 − α2β3  \uf8f6  \uf8f8  31  ⊕ P6(0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' i)  √  2  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ed  α1β1 − α2β4  α1β2 − α2β5  α1β3 − α2β6  −α1β4 − α2β1  −α1β5 − α2β2  −α1β6 − α2β3  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f8  6  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='\uf8f7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='\uf8f7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='\uf8f8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  20  Here we have used the notations,  P2 =  � 0  1  −1  0  �  ,  P3 =  \uf8eb  \uf8ed  0  0  1  1  0  0  0  1  0  \uf8f6  \uf8f8 ,  P6(r, i) =  � 03  13  −13  03  �r �P3  03  03  P3  �i  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (79)  Further details can be found in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' [33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  B  Modular forms of Γ6  Here we give a review on the modular forms of Γ6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' The modular forms of level 6 of even weights  can be constructed from the products of the Dedekind eta function [33],  η(τ) = q1/24  ∞  �  n=1  (1 − qn),  q = e2πiτ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (80)  Using η,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' four linearly independent modular forms of weight 2 can be written down as  Y (2)  30 (τ) =  \uf8eb  \uf8ed  −Y 2  1  √  2Y1Y2  Y 2  2  \uf8f6  \uf8f8 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (2)  11  2 (τ) = Y3Y6 − Y4Y5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (2)  20 (τ) = 1  √  2  �Y1Y4 − Y2Y3  Y1Y6 − Y2Y5  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (81)  Y (2)  6 (τ) = 1  √  2  \uf8eb  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ec  \uf8ed  Y1Y4 + Y2Y3  √  2Y2Y4  −  √  2Y1Y3  Y1Y6 + Y2Y5  √  2Y2Y6  −  √  2Y1Y5  \uf8f6  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f7  \uf8f8  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (82)  where  Y1(τ) = 3η3(3τ)  η(τ) + η3(τ/3)  η(τ) ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (83)  Y2(τ) = 3  √  2η3(3τ)  η(τ) ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (84)  Y3(τ) = 3  √  2η3(6τ)  η(2τ) ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (85)  Y4(τ) = −3η3(6τ)  η(2τ) − η3(2τ/3)  η(2τ) ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (86)  Y5(τ) =  √  6η3(6τ)  η(2τ) −  √  6η3(3τ/2)  η(τ/2) ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (87)  Y6(τ) = −  √  3η3(6τ)  η(2τ) + 1  √  3  η3(τ/6)  η(τ/2) − 1  √  3  η3(2τ/3)  η(2τ)  +  √  3η3(3τ/2)  η(τ/2) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (88)  21  Then we can construct the modular forms of weight 4 by the CG coefficients shown in appendix  A as  Y (4)  10  0 (τ) =  �  Y (2)  20 Y (2)  20  �  10  0  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (4)  10  1 (τ) =  �  Y (2)  11  2 Y (2)  11  2  �  10  1  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (4)  20 (τ) =  �  Y (2)  20 Y (2)  20  �  20 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (89)  Y (4)  22 (τ) =  �  Y (2)  11  2 Y (2)  20  �  22 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (4)  30 (τ) =  �  Y (2)  20 Y (2)  6  �  30 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (4)  31 (τ) =  �  Y (2)  11  2 Y (2)  30  �  31 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (90)  Y (4)  6i (τ) =  �  Y (2)  11  2 Y (2)  6  �  6 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (4)  6ii (τ) =  �  Y (2)  20 Y (2)  30  �  6 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (91)  Note that Y (4)  6i  and Y (4)  6ii stand for two linearly independent six-dimensional modular forms of  weight 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' We use the same convention for other modular forms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Similarly,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' we construct the  modular forms of weight 6 as  Y (6)  10  0 (τ) =  �  Y (2)  20 Y (4)  20  �  10  0  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  11  0 (τ) =  �  Y (2)  11  2 Y (4)  10  1  �  11  0  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  11  2 (τ) =  �  Y (2)  11  2 Y (4)  10  0  �  11  2  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (92)  Y (6)  20 (τ) =  �  Y (2)  20 Y (4)  10  0  �  20 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  21 (τ) =  �  Y (2)  20 Y (4)  10  1  �  21 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  22 (τ) =  �  Y (2)  11  2 Y (4)  20  �  22 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (93)  Y (6)  30i(τ) =  �  Y (2)  30 Y (4)  10  1  �  30 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  30ii(τ) =  �  Y (2)  30 Y (4)  10  0  �  30 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  31 (τ) =  �  Y (2)  11  2 Y (4)  30  �  31 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (94)  Y (6)  6i (τ) =  �  Y (2)  20 Y (4)  31  �  6 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  6ii (τ) =  �  Y (2)  6 Y (4)  10  0  �  6 ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (6)  6iii(τ) =  �  Y (2)  30 Y (4)  20  �  6 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (95)  In Table 8 we summarize the modular forms of level 6 of even weights up to 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Modular form Y (kY )  r  kY = 2  Y (2)  11  2 , Y (2)  20 , Y (2)  30 , Y (2)  6  kY = 4  Y (4)  10  0 , Y (4)  10  1 , Y (4)  20 , Y (4)  22 , Y (4)  30 , Y (4)  31 , Y (4)  6i , Y (4)  6ii  kY = 6  Y (6)  10  0 , Y (6)  11  0 , Y (6)  11  2 , Y (6)  20 , Y (6)  21 , Y (6)  22 , Y (6)  30i, Y (6)  30ii, Y (6)  31 , Y (6)  6i , Y (6)  6ii , Y (6)  6iii  Table 8: The modular forms of level 6 of even weights up to 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Also we construct the singlet modular forms of weights 8, 10, 12 and 14 which we have used  in our analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' First, the singlet modular forms of weight 8 are given by  Y (8)  10  0 =  �  Y (4)  10  0 Y (4)  10  0  �  10  0  ,  Y (8)  10  1 =  �  Y (4)  10  0 Y (4)  10  1  �  10  1  ,  Y (8)  10  2 =  �  Y (4)  10  1 Y (4)  10  1  �  10  2  ,  Y (8)  11  2 =  �  Y (4)  20 Y (4)  22  �  11  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (96)  The singlet modular forms of weight 10 are given by  Y (10)  10  0  =  �  Y (4)  10  0 Y (6)  10  0  �  10  0  ,  Y (10)  10  1  =  �  Y (4)  10  1 Y (6)  10  0  �  10  1  ,  Y (10)  11  0  =  �  Y (4)  10  0 Y (6)  11  0  �  11  0  ,  (97)  Y (10)  11  1  =  �  Y (4)  10  1 Y (6)  11  0  �  11  1  ,  Y (10)  11  2  =  �  Y (4)  10  0 Y (6)  11  2  �  11  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (98)  22  The singlet modular forms of weight 12 are given by  Y (12)  10  0i =  �  Y (6)  10  0 Y (6)  10  0  �  10  0  ,  Y (12)  10  0ii =  �  Y (6)  11  0 Y (6)  11  0  �  10  0  ,  Y (12)  10  1  =  �  Y (6)  11  2 Y (6)  11  2  �  10  1  ,  (99)  Y (12)  10  2  =  �  Y (6)  11  0 Y (6)  11  2  �  10  2  ,  Y (12)  11  0  =  �  Y (6)  10  0 Y (6)  11  0  �  11  0  ,  Y (12)  11  2  =  �  Y (6)  10  0 Y (6)  11  2  �  11  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (100)  The singlet modular forms of weight 14 are given by  Y (14)  10  0  =  �  Y (6)  10  0 Y (8)  10  0  �  10  0  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (14)  10  1  =  �  Y (6)  10  0 Y (8)  10  1  �  10  1  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (14)  10  2  =  �  Y (6)  10  0 Y (8)  10  2  �  10  2  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (101)  Y (14)  11  0  =  �  Y (6)  11  0 Y (8)  10  0  �  11  0  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (14)  11  1  =  �  Y (6)  11  0 Y (8)  10  1  �  11  1  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Y (14)  11  2i =  �  Y (6)  11  2 Y (8)  10  0  �  11  2  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (102)  Y (14)  11  2ii =  �  Y (6)  11  0 Y (8)  10  2  �  11  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  (103)  In Table 9 we summarize the singlet modular forms of level 6 of weights 8, 10, 12 and 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Modular form Y (kY )  r  kY = 8  Y (8)  10  0 , Y (8)  10  1 , Y (8)  10  2 , Y (8)  11  2  kY = 10  Y (10)  10  0 , Y (10)  10  1 , Y (10)  11  0 , Y (10)  11  1 , Y (10)  11  2  kY = 12  Y (12)  10  0i , Y (12)  10  0ii, Y (12)  10  1 , Y (12)  10  2 , Y (12)  11  0 , Y (12)  11  2  kY = 14  Y (14)  10  0 , Y (14)  10  1 , Y (14)  10  2 , Y (14)  11  0 , Y (14)  11  1 , Y (14)  11  2i , Y (14)  11  2ii  Table 9: The singlet modular forms of level 6 of weights 8, 10, 12 and 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  23  References  [1] F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Feruglio, in From My Vast Repertoire .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=': Guido Altarelli’s Legacy, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Levy, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Forte,  Stefano, and G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Ridolfi, eds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=', pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='227–266, 2019, arXiv:1706.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='08749 [hep-ph].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  [2] S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Ferrara, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Lust, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Shapere and S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Theisen, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' B 225, 363 (1989).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  [3] S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Ferrara, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Lust and S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' de Adelhart Toorop, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Feruglio and C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Hagedorn, Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' B 858, 437 (2012)  [arXiv:1112.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' Mod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' Ishimori, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Kobayashi, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Ohki, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Shimizu, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Okada and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' Theor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Suppl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 183 (2010) 1 [arXiv:1003.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='3552 [hep-th]].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content='  [20] H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Ishimori, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Kobayashi, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Ohki, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Okada, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Shimizu and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Tanimoto, Lect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Notes  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 858 (2012) 1, Springer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' Ohki, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Okada, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Shimizu and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Tanimoto, Lect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' Notes Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
+page_content=' 995  (2022) 1, Springer doi:10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+page_content='  28' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/2NE2T4oBgHgl3EQfNgYt/content/2301.03737v1.pdf'}
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+Temperature and density effects on the two-nucleon momentum correlation function
+from excited single nuclei
+Ting-Ting Wang(王婷婷),1 Yu-Gang Ma(马余刚),1, 2 De-Qing Fang(方德清),1, 2 and Huan-Ling Liu(刘焕玲)3
+1Key Laboratory of Nuclear Physics and Ion-Beam Application (MOE),
+Institute of Modern Physics, Fudan University, Shanghai 200433, China
+2Shanghai Research Center for Theoretical Nuclear Physics，NSFC and Fudan University, Shanghai 200438, China
+3Shanghai Institute of Applied Physics, Chinese Academy of Sciences, Shanghai 201800, China
+(Dated: January 10, 2023)
+Two-nucleon momentum correlation functions are investigated for different single thermal sources
+at given initial temperature (T) and density (ρ). To this end, the space-time evolutions of various
+single excited nuclei at T = 1 − 20 MeV and ρ = 0.2 - 1.2 ρ0 are simulated by using the ther-
+mal isospin-dependent quantum molecular dynamics (ThIQMD) model. Momentum correlation
+functions of identical proton-pairs (Cpp(q)) or neutron-pairs (Cnn(q)) at small relative momenta
+are calculated by Lednick´y and Lyuboshitz analytical method. The results illustrate that Cpp(q)
+and Cnn(q) are sensitive to the source size (A) at lower T or higher ρ, but almost not at higher
+T or lower ρ. And the sensitivities become stronger for smaller source. Moreover, the T, ρ and A
+dependencies of the Gaussian source radii are also extracted by fitting the two-proton momentum
+correlation functions, and the results are consistent with the above conclusions.
+I.
+INTRODUCTION
+Properties of nuclear matter is one of the most in-
+teresting topics in heavy-ion physics
+[1–4] and lots of
+works have been done around zero temperature, includ-
+ing the nuclear equation of state (EOS). However, the
+studies on properties of nuclear matter at finite tem-
+peratures are relatively limited.
+Many previous works
+mainly focus on the temperature dependence of hot nu-
+clear matter and the nuclear liquid-gas phase transition
+(LGPT) [5–14], the ratio between shear viscosity over
+entropy density (η/s) [15–19], as well as the nuclear gi-
+ant dipole resonance [20–22] etc. Among above works,
+the relationship between the phase transition tempera-
+ture and the source size has been investigated [5].
+In
+Ref. [5], the finite-size scaling effects on nuclear liquid-
+gas phase transition probes are investigated by study-
+ing de-excitation processes of the thermal sources by the
+isospin-dependent quantum molecular dynamics model
+(IQMD). Several probes, including the total multiplicity
+derivative, second moment parameter, intermediate mass
+fragment multiplicity, Fisher,s power-law exponent as
+well as nuclear Zipf ,s law exponent of Ma [9] were ex-
+plored, and the phase transition temperatures were then
+obtained.
+Recently, the deep neural network has also
+been used to determine the nuclear liquid gas phase tran-
+sition [23] and to estimate the temperature of excited
+nuclei by the charge multiplicity distribution of emitted
+fragments [24]. The latter work proposed that the charge
+multiplicity distribution can be used as a thermometer of
+heavy-ion collisions.
+Considering that the intermediate-state at high tem-
+perature and density in the evolution process of nuclear
+reactions cannot be directly measured, one always ex-
+plore properties of nuclear matter and the dynamical
+description of heavy-ion collisions through the analysis
+of the final-state products.
+As well known, the two-
+particle momentum correlation function in the final-state
+has been extensively used as a probe of the space-time
+properties and characteristics of the emission source [25–
+27]. The two-proton momentum correlation function has
+been explored systematically by a lot of experiments as
+well as different models, several reviews can be found
+in Refs. [28–31]. In various studies on the momentum
+correlation function, impacts of the impact parameter,
+the total momentum of nucleon pairs, the isospin of the
+emission source, the nuclear symmetry energy, the nu-
+clear equation of state (EOS) as well as the in-medium
+nucleon-nucleon cross section have been discussed in lit-
+erature [32–38].
+Even more, nuclear structure effects
+were also carefully investigated, such as the effects from
+binding energy and separation energy of the nucleus [39],
+density distribution of valence neutrons in neutron-rich
+nuclei [40], as well as high momentum tail of the nucleon-
+momentum distribution [41] etc. Two-proton momentum
+correlation function was also constructed in few-body re-
+actions as well as α-clustered nucleus induced collisions
+[42–46]. In addition, momentum correlation function be-
+tween two light charged particles also offers a unique
+tool to investigate dynamical expansion of the reaction
+zone [38].
+Here we extend the momentum correlation method
+of final-state interaction to study the time-spatial infor-
+mation of the finite-temperature nuclear systems which
+have different initial density. The purpose of the present
+paper is to systematically investigate the relationship
+between two-particle momentum correlation functions
+and system parameters, such as the source-temperature,
+density as well as system-size in a framework of the
+thermal isospin-dependent quantum molecular dynamics
+(ThIQMD) model
+[5, 14, 17]. In addition, the Gaus-
+sian source radii are quantitatively extracted by assump-
+tion of Gaussian source fits to the momentum correla-
+tion function distributions. In this article, the evolution
+process of excited nuclear sources at given initial tem-
+arXiv:2301.02849v1  [nucl-th]  7 Jan 2023
+
+2
+peratures varying from 1 MeV to 20 MeV are studied.
+The present work selects six different nuclear systems
+with similar ratio of neutron to proton numbers, i.e.,
+N/Z ∼ 1.3, which include (A, Z) = (36, 15), (52, 24),
+(80, 33), (100, 45), (112, 50), and (129, 54) nuclei. Then,
+Lednick´y-Lyuboshitz theoretical approach [47] is applied
+for calculating two-particle momentum correlation func-
+tions which are constructed based on phase-space infor-
+mation from the evolution process of single excited nu-
+clear sources by the ThIQMD model.
+The rest of this article is organized as follows. In Sec-
+tion II, we firstly describe the thermal isospin-dependent
+quantum molecular dynamics model [14, 17], then briefly
+introduce the momentum correlation technique using
+Lednick´y and Lyuboshitz analytical formalism. In Sec-
+tion III, we show the results of the ThIQMD plus
+the LL method for the source-temperature dependence
+of two-particle momentum correlation function.
+The
+two-particle momentum correlation functions of differ-
+ent system-sizes at different initial densities are sys-
+tematically discussed. The detailed analysis of the ex-
+tracted Gaussian source radii are presented under differ-
+ent source-temperature and density.
+Furthermore, the
+momentum correlation function of two-neutron is also
+analyzed. Finally, Section IV gives a summary of the
+paper.
+II.
+MODELS AND FORMALISM
+A.
+THE ThIQMD MODEL
+In this paper, the thermal isospin-dependent Quan-
+tum Molecular Dynamics transport model is used as
+the event generator, which has been applied success-
+fully to study the LGPT [5, 24].
+In the following
+discussion, we introduce this model briefly.
+As well
+known, isospin-dependent Quantum Molecular Dynam-
+ics (IQMD) model was used to describe the collision
+process between two nuclei.
+The Quantum Molecular
+Dynamics transport model is a n-body transport theory,
+which describes heavy-ion reaction dynamics from inter-
+mediate to relativistic energies [48–51]. In the present
+work, we use a single excited source in the ThIQMD
+which is different from the traditional IQMD. Usually,
+the ground state of the initial nucleus is considered to be
+T = 0 MeV in the traditional IQMD model. However,
+the ThIQMD model developed by Fang, Ma, and Zhou
+in Ref. [17] is used to simulate single thermal source at
+different temperatures and densities.
+The main parts of QMD transport model include the
+following issues: the initialization of the projectile and
+the target, nucleon propagation under the effective po-
+tential, the collisions between the nucleons in the nuclear
+medium and the Pauli blocking effect. In the ThIQMD,
+instead of using the Fermi-Dirac distribution for T = 0
+MeV with the nucleon’s maximum momentum limited
+by P i
+F (⃗r) = ℏ
+�
+3π2ρi(⃗r)
+�1/3, the initial momentum of nu-
+cleons is sampled by the Fermi-Dirac distribution at finite
+temperature:
+n (ek) =
+g (ek)
+e
+ek−µi
+T
++ 1
+,
+(1)
+where the kinetic energy ek =
+p2
+2m, p and m is the mo-
+mentum and mass of the nucleon, respectively. g (ek) =
+V
+2π2
+� 2m
+ℏ2
+� 3
+2 √ek represents the state density with the vol-
+ume of the source V = 4
+3πr3 where r = rV A
+1
+3 (rV is a
+parameter to adjust the initial density).
+In addition, the chemical potential µi is determined by
+the following equation:
+1
+2π2
+�2m
+ℏ2
+� 3
+2 � ∞
+0
+√ek
+e
+ek−µi
+T
++ 1
+dek = ρi.
+(2)
+where i = n or p refer to the neutron or proton.
+In the ThIQMD model, the interaction potential is
+also represented by the form as follows:
+U = USky + UCoul + UY uk + USym + UMDI,
+(3)
+where USky, UCoul, UY uk, USym, and UMDI are the
+density-dependent Skyrme potential, the Coulomb po-
+tential, the surface Yukawa potential, the isospin asym-
+metry potential, and the momentum-dependent interac-
+tion, respectively. Among these potentials, the Skyrme
+potential, the Coulomb potential and the momentum-
+dependent interaction can be written as follows:
+USky = α( ρ
+ρ0
+) + β( ρ
+ρ0
+)γ,
+(4)
+where ρ and ρ0 are total nucleon density and its normal
+value at the ground state, i.e., 0.16 fm−3, respectively.
+The above parameters α, β, and γ with an incompress-
+ibility parameter K are related to the nuclear equation
+of state [52–58].
+USym = Csym
+(ρn − ρp)
+ρ0
+τz,
+(5)
+UCoul = 1
+2 (1 − τz) Vc,
+(6)
+where ρn and ρp are neutron and proton densities, re-
+spectively, τz is the z-th component of the isospin degree
+of freedom for the nucleon, which equals 1 or −1 for a
+neutron or proton, respectively, and Csym is the symme-
+try energy coefficient. UCoul is the Coulomb potential
+where Vc is its parameter for protons.
+UMDI = δ · ln2 �
+ϵ · (∆p)2 + 1
+�
+· ρ
+ρ0
+,
+(7)
+where ∆p is the relative momentum, δ and ϵ can be found
+in Refs. [48, 49].
+Their values of the above potential
+parameters are all listed in Table I:
+
+3
+TABLE I. The value of the interaction potential parameters.
+α
+β
+γ
+K
+δ
+ϵ
+(MeV ) (MeV )
+(MeV ) (MeV ) ((GeV/c)−2)
+−390.1
+320.3
+1.14
+200
+1.57
+500
+B.
+LEDNICK ´Y AND LYUBOSHITZ
+ANALYTICAL FORMALISM
+Next, we briefly review the method for the two-particle
+momentum correlation function proposed by Lednick´y
+and Lyuboshitz [47, 59, 60]. The momentum correlation
+technique in nuclear collisions is based on the principle
+as follows: when they are emitted at small relative mo-
+mentum, the two-particle momentum correlation is deter-
+mined by the space-time characteristics of the production
+processes owing to the effects of quantum statistics (QS)
+and final-state interactions (FSI) [61, 62].
+Therefore,
+the two-particle momentum correlation function can be
+expressed through a square of the symmetrizied Bethe-
+Salpeter amplitude averaging over the four coordinates
+of the emitted particles and the total spin of the two-
+particle system, which represents the continuous spec-
+trum of the two-particle state.
+In this theoretical approach, the final-state interactions
+of the particle pairs is assumed independent in the pro-
+duction process. According to the conditions in Ref. [63],
+the correlation function of two particles can be written
+as the expression:
+C (k∗) =
+�
+S (r∗, k∗) |Ψk∗ (r∗)|2 d4r∗
+�
+S (r∗, k∗) d4r∗
+,
+(8)
+where r∗ = x1 − x2 is the relative distance of the two
+particles in the pair rest frame (PRF) at their kinetic
+freeze-out, k∗ is half of the relative momentum between
+two particles in the PRF, S (r∗, k∗) is the probability to
+emit a particle pair with given r∗ and k∗, i.e., the source
+emission function, and Ψk∗ (r∗) is the equal-time (t∗ = 0)
+reduced Bethe-Salpeter amplitude which can be approx-
+imated by the outer solution of the scattering problem in
+the PRF [64, 65]. This approximation is valid on condi-
+tion |t∗| ≪ m (r∗)2, which is well fulfilled for sufficiently
+heavy particles like protons or kaons and reasonably ful-
+filled even for pions [59]. In the above limit, the asymp-
+totic solution of the wave function of the two charged
+particles approximately takes the expression:
+Ψk∗ (r∗) = eiδc�
+Ac (λ)×
+�
+e−ik∗r∗F (−iλ, 1, iξ) + fc (k∗)
+˜G (ρ, λ)
+r∗
+�
+.
+(9)
+In the above equation, δc = arg Γ (1 + iλ) is the Coulomb
+s-wave phase shift with λ = (k∗ac)−1 where ac is the two-
+particle Bohr radius, Ac (λ) = 2πλ [exp (2πλ) − 1]−1 is
+the Coulomb penetration factor, and its positive (neg-
+ative) value corresponds to the repulsion (attraction).
+˜G (ρ, λ) =
+�
+Ac (λ) [G0 (ρ, λ) + iF0 (ρ, λ)] is a combina-
+tion of regular (F0) and singular (G0) s-wave Coulomb
+functions [59, 60]. F (−iλ, 1, iξ) = 1 + (−iλ) (iξ) /1!2 +
+(−iλ) (−iλ + 1) (iξ)2 /2!2 + · · · is the confluent hyperge-
+ometric function with ξ = k∗r∗ + ρ, ρ = k∗r∗.
+fc (k∗) =
+�
+Kc (k∗) − 2
+ac
+h (λ) − ik∗Ac (λ)
+�−1
+(10)
+is the s-wave scattering amplitude renormalizied by
+the long-range Coulomb interaction,
+with h (λ)
+=
+λ2 �∞
+n=1
+�
+n
+�
+n2 + λ2��−1−C −ln [λ] where C = 0.5772 is
+the Euler constant. Kc (k∗) =
+1
+f0 + 1
+2d0k∗2 +Pk∗4 +· · · is
+the effective range function, where d0 is the effective ra-
+dius of the strong interaction, f0 is the scattering length
+and P is the shape parameter. The parameters of the
+effective range function are important parameters char-
+acterizing the essential properties of the FSI, and can
+be extracted from the correlation function measured ex-
+perimentally [38, 65–67].
+For n-n momentum correlation functions which include
+uncharged particle, only the short-range particle inter-
+action works. For p-p momentum correlation functions,
+both the Coulomb interaction and the short-range parti-
+cle interaction dominated by the s-wave interaction are
+taken into account.
+III.
+ANALYSIS AND DISCUSSION
+Within
+the
+framework
+of
+the
+thermal
+isospin-
+dependent
+quantum
+molecular
+dynamics
+model
+[5,
+14, 17], the two-particle momentum correlation func-
+tions are calculated by using the phase-space infor-
+mation from the freeze-out stage of the excited nu-
+clear source at an initial temperature varying from 1
+MeV
+to 20 MeV
+and/or density varying from ρ =
+0.2ρ0 to 1.2ρ0.
+This work performs calculations for
+thermal source systems with different mass including
+(A, Z)
+=
+(36, 15), (52, 24), (80, 33), (100, 45), (112, 50),
+and (129, 54).
+We firstly calculated the proton-proton momentum
+correlation function Cpp(q) for finite-size systems at tem-
+peratures ranging from 1 to 20 MeV .
+In Fig. 1, the
+results of Cpp(q) for temperature of 2, 4, 6, 8, 10 and
+12 MeV at different values of density (0.2ρ0 - 1.2ρ0)
+are presented.
+The proton-proton momentum correla-
+tion function exhibits a peak at relative momentum q =
+20 MeV/c, which is due to the strong final-state s-wave
+attraction together with the suppression at lower rela-
+tive momentum as a result of Coulomb repulsion and the
+antisymmetrization wave function between two protons.
+The shape of the two-proton momentum correlation func-
+tions is consistent with many previous experimental data
+in heavy-ion collisions, eg. Ref. [68]. For protons which
+are emitted from the lower temperature (T < 8 MeV )
+source in Fig. 1 (a)-(c), the general trend is very similar.
+The figure shows that Cpp(q) increases as ρ increases for
+
+4
+0.5
+1.0
+1.5
+2.0
+2.5
+0.5
+1.0
+1.5
+2.0
+2.5
+20
+40
+60
+80
+0.5
+1.0
+1.5
+2.0
+2.5
+20
+40
+60
+80
+(a) T = 2.0 MeV
+ ρ = 0.2 ρ0 
+ ρ = 0.4 ρ0 
+ ρ = 0.6 ρ0 
+ ρ = 0.8 ρ0 
+ ρ = 1.0 ρ0 
+ ρ = 1.2 ρ0
+Cpp(q)
+(d) T = 8.0 MeV
+(b) T = 4.0 MeV
+(e) T = 10.0 MeV
+(c) T = 6.0 MeV
+(f) T = 12.0 MeV
+q (MeV/c)
+FIG. 1.
+The proton-proton momentum correlation function
+(Cpp(q)) at different densities (i.e., 0.2ρ0, 0.4ρ0, 0.6ρ0, 0.8ρ0,
+1.0ρ0, and 1.2ρ0) for the smaller nucleus (A=36, Z=15) with
+fixed source-temperatures T = 2 MeV (a), 4 MeV (b), 6
+MeV (c), 8 MeV (d), 10 MeV (e) and 12 MeV (f), respec-
+tively. The freeze-out time is taken to be 200 fm/c.
+fixed T (T < 8 MeV ). The increase of the density in-
+dicates that the geometrical size becomes smaller for a
+source with fixed neutrons and protons, which makes the
+strength of the momentum correlation function stronger.
+Finally, the p-p momentum correlation function becomes
+almost one at q > 60 MeV/c.
+For larger T (T > 8
+MeV ) in Fig. 1 (d)-(f), the difference of Cpp(q) between
+different densities becomes smaller.
+From Fig. 1, it is
+found that the Cpp(q) almost keep the same above T = 8
+MeV for different densities and the p-p momentum cor-
+relation function becomes almost unique above approx-
+imately q = 30 MeV/c.
+It indicates that the emitted
+proton is not affected by the change of density when the
+source temperature beyond certain value (T ≈ 8 MeV in
+present work). In order to understand which one of the
+two factors (i.e., temperature and density) has larger in-
+fluence, the two-particle momentum correlation in fig. 2
+is plotted by exchanging of the two input parameters.
+From fig. 2, we can intuitively observe dependence of the
+two-particle momentum correlation on the source tem-
+perature. The dependence of Cpp(q) on the source tem-
+perature is stronger than on density.
+In other words,
+the Cpp(q) is more sensitive to T than to density ρ. In
+0.5
+1.0
+1.5
+2.0
+2.5
+0.5
+1.0
+1.5
+2.0
+2.5
+20
+40
+60
+80
+0.5
+1.0
+1.5
+2.0
+2.5
+20
+40
+60
+80
+(d) ρ = 0.8 ρ0
+(a) ρ = 0.2 ρ0
+ Τ =  2 MeV 
+ Τ =  8 MeV
+ Τ =  4 MeV 
+ Τ =  10 MeV
+ Τ =  6 MeV 
+ Τ =  12 MeV 
+Cpp(q)
+(c) ρ = 0.6 ρ0
+(b) ρ = 0.4 ρ0
+(f) ρ = 1.2 ρ0
+(e) ρ = 1.0 ρ0
+q (MeV/c)
+ 
+FIG. 2.
+Similar to Fig. 1, but at different source-
+temperatures (T = 2, 4, 6, 8, 10 and 12 MeV ) with different
+fixed densities, namely ρ = 0.2ρ0 (a), 0.4 ρ0 (b), 0.6 ρ0 (c),
+0.8 ρ0 (d), 1.0 ρ0 (e), and 1.2ρ0 (f).
+addition, for larger ρ from fig. 2 (a) to (f), the differ-
+ence of Cpp(q) between different densities becomes bigger.
+Next, we explore whether the phenomenon exists in mo-
+mentum correlation functions for the uncharged-particle
+pairs. Fig. 3 presents the neutron-neutron momentum
+correlation functions (Cnn(q)) for temperature of 2, 4,
+6, 8, 10 and 12 MeV at different values of density, re-
+spectively. For neutron-neutron momentum correlation
+function, it peaks at q ≈ 0 MeV/c caused by the s-wave
+attraction. Although the Cnn(q) has different shape com-
+pared with the p-p momentum correlation function, it has
+the similar dependence on the source temperature and
+density. The similar trend in Cpp(q) and Cnn(q) shows
+the close emission mechanism in the evolution process.
+Fig. 4 shows the results of a larger system at differ-
+ent source-temperature and density, and a similar be-
+havior of Cpp(q) is demonstrated. We also observe that
+the proton-proton momentum correlation in larger-size
+system ((A, Z) = (129, 54)) in Fig. 4 becomes weaker
+in comparison with the smaller-size source ((A, Z) =
+(36, 15)) in Fig. 1. In view of the above phenomenon,
+Fig. 5 describes the relationship between system-size and
+momentum correlation function in more details.
+The
+decreasing of Cpp(q) as the system-size increasing for a
+fixed value of T or ρ can be clearly seen in Fig. 5 (g),
+
+5
+2
+4
+6
+8
+10
+12
+14
+2
+4
+6
+8
+10
+12
+14
+20
+40
+60
+80
+2
+4
+6
+8
+10
+12
+14
+20
+40
+60
+80
+(b) T = 4.0 MeV
+(a) T = 2.0 MeV
+ ρ = 0.2 ρ0 
+ ρ = 0.4 ρ0 
+ ρ = 0.6 ρ0 
+ ρ = 0.8 ρ0 
+ ρ = 1.0 ρ0 
+ ρ = 1.2 ρ0
+(d) T = 8.0 MeV
+(e) T = 10.0 MeV
+(c) T = 6.0 MeV
+q (MeV/c)
+Cnn(q)
+(f) T = 12.0 MeV
+FIG. 3.
+The neutron-neutron (n-n) momentum correlation
+functions (Cnn(q)) in the same conditions as Fig. 1.
+which is consistent with the previous results of Gaussian
+source [37, 38, 69]. In Fig. 5 (a)-(i), with larger temper-
+ature or lower density, the difference of Cpp(q) between
+different T or ρ becomes smaller, respectively. The Gaus-
+sian source radii are extracted for further discussion later
+in this article.
+From the above plots, we can extract Cmax(q), i.e.,
+the maximum value of Cpp(q) as well as the full width at
+half maximum (FWHM) of Cpp(q) distribution, i.e. at
+Cpp(q) = [Cmax(q)−1]/2. The source-temperature T de-
+pendence of Cmax(q) and FWHM for the proton-proton
+momentum correlation function with different density are
+given in Fig. 6. As shown in Fig. 6 (a) and (b), both
+Cmax(q) and FWHM decrease gradually with the in-
+creasing of T. In addition, both of them increase grad-
+ually with density.
+At high temperature, the change
+of Cmax(q) and FWHM is very small and not plotted
+in the figure.
+Of course, the behavior of the Cmax(q)
+and FWHM with T and ρ can also be clearly seen in
+Fig. 2, and the increasing of Cmax(q) and FWHM are
+generally inversely proportional to Gaussian radius r0 as
+shown later.
+Similarly, the system-size A dependence
+of Cmax(q) and FWHM for the proton-proton momen-
+tum correlation function at T = 2MeV and ρ = 0.6ρ0
+is shown in Fig. 7.
+The dependence of Cmax(q) and
+FWHM on system-size A is quite similar to the temper-
+ature dependence in Fig. 6. The Cmax(q) and FWHM
+0.5
+1.0
+1.5
+2.0
+2.5
+0.5
+1.0
+1.5
+2.0
+2.5
+20
+40
+60
+80
+0.5
+1.0
+1.5
+2.0
+2.5
+20
+40
+60
+80
+(a) T = 2.0 MeV
+ ρ = 0.2 ρ0 
+ ρ = 0.4 ρ0 
+ ρ = 0.6 ρ0 
+ ρ = 0.8 ρ0 
+ ρ = 1.0 ρ0 
+ ρ = 1.2 ρ0
+(d) T = 8.0 MeV
+(b) T = 4.0 MeV
+(e) T = 10.0 MeV
+(c) T = 6.0 MeV
+(f) T = 12.0 MeV
+Cpp(q)
+q (MeV/c)
+FIG. 4.
+Same to Fig. 1, but for a larger system (A=129,
+Z=54).
+values become smaller for larger systems.
+Fig. 8 shows the source-temperature, density, and
+system-size dependence of Gaussian radii extracted from
+two-particle momentum correlation functions,
+where
+panels (a) and (b) are results with the smaller source
+size and the larger source size, respectively. The radii
+are extracted by a Gaussian source assumption, i.e.,
+S(r) ≈ exp[−r2/(4r2
+0)], where r0 is the Gaussian source
+radius from the proton-proton momentum correlation
+functions.
+The theoretical calculations for Cpp(q) was
+performed by using the Lednick´y and Lyuboshitz an-
+alytical method.
+The best fitting radius is judged by
+finding the minimum of the reduced chi-square between
+the ThIQMD calculations and the Gaussian source as-
+sumption. Since the effect of the strong FSI scales as
+fc (k∗) /r∗ in Eq. (9), one may read the sensitivity of
+the correlation function to the temperature T, density
+ρ and atomic number A from their effects on the Gaus-
+sian radius r0. One may observe a linear dependence on
+these parameters up to T ≈ 8 MeV and then a lost of
+sensitivity in a plateau region at higher temperatures in
+Fig. 8. As the density decreases, the decreasing speed of
+the Gaussian radius of the small system is larger than
+that of the larger system. Fig. 9 shows the Gaussian ra-
+dius of the different system-size varies with the temper-
+ature in panels (a)-(c) or density in panels (d)-(f). The
+Gaussian source radius is consistent with the system-size,
+
+6
+0.5
+1.0
+1.5
+2.0
+0.5
+1.0
+1.5
+2.0
+40
+80
+0.5
+1.0
+1.5
+2.0
+40
+80
+40
+80
+(a)
+ρ = 1.0ρ0
+ρ = 0.6ρ0
+ρ = 0.2ρ0
+T = 6 MeV
+T = 4 MeV
+ A = 36     
+ A = 52 
+ A = 80     
+ A = 96   
+ A = 100   
+ A = 112   
+ A = 129
+ 
+ 
+ 
+ 
+T = 2 MeV
+(b)
+(c)
+(d)
+(g)
+(e)
+(f)
+(h)
+(i)
+Cpp(q)
+q (MeV/c)
+FIG. 5.
+Cpp(q) of different source size systems at fixed temperatures (i.e., from left column to right column, they correspond
+to T = 2, 4 and 6 MeV , respectively) or fixed densities (i.e., from top row to bottom row, they correspond to ρ = 0.2ρ0, 0.6ρ0,
+1.0ρ0, respectively).
+i.e., at higher temperature or larger density, the differ-
+ences of Gaussian source between different system sizes
+are bigger in the low density and low temperature region,
+but the difference in opposite conditions almost disap-
+pear. In other words, the sensitivity of the source radii
+to the system size seem to be different in the different
+regions of temperatures and densities. For example, the
+sensitivity is better in the region of lower T and higher ρ
+(Fig. 9(b) and (c)), or it is better in the higher T region
+for the lower ρ (Fig. 9(a)), or it is better in the higher ρ
+region for the lower T (Fig. 9(d)).
+From the above discussion, it is demonstrated that
+the strength of the two-particle momentum correlation
+function is affected by the source temperature, density
+and system size. The two-particle momentum correlation
+function strength is larger for a single source with lower
+temperature, higher density or smaller mass number as
+shown in Fig. 1-5.
+Otherwise, the strength becomes
+smaller. To some extents, the strong correlation between
+two particles is mainly caused by the closed position of
+each other in phase space in both coordinate and momen-
+tum. Varying only one in the three condition parameters
+(temperature, density and system size), lower temper-
+ature means smaller momentum space, higher density
+means smaller coordinate space and small system size
+also mean smaller coordinate space to keep fixed den-
+sity compared with large system size.
+The dependen-
+cies of the two-particle momentum correlation function
+strength on the source temperature, density and system
+size could be explained by the change of the phase space
+sizes. Two particles emitted from small phase space will
+have strong correlation and those from large phase space
+will have weak correlation. For example, the increase of
+the Cpp(q) strength with the increase of the density for
+
+7
+1.0
+1.5
+2.0
+2.5
+2
+3
+4
+5
+6
+4
+6
+8
+10
+12
+(a)
+ ρ = 0.2 ρ0 
+ ρ = 0.4 ρ0 
+ ρ = 0.6 ρ0 
+ ρ = 0.8 ρ0 
+ ρ = 1.0 ρ0 
+ ρ = 1.2 ρ0
+Cmax(q)
+(b)
+FWHM (Mev/c)
+T (MeV)
+FIG. 6.
+Source-temperature T dependencies of Cmax(q)
+(a) and of FWHM (b) of Cpp(q) distributions at different
+densities (0.2ρ0 - 1.2ρ0) for the (A = 35, Z = 16) system.
+1.4
+1.6
+1.8
+40
+60
+80
+100
+120
+6.0
+6.5
+7.0
+7.5
+8.0
+8.5
+(a)
+y = b+a*x    value
+    a
+       -0.0055
+    b
+        2.0358
+Cmax(q)
+ Cmax(q)
+ Fitting curve
+(b)
+y = b+a*x    value
+    a
+       -0.022
+    b
+        8.913
+A
+FWHM (Mev/c)
+ FWHM
+ Fitting curve
+FIG. 7.
+Cmax(q) (a) and FWHM (b) for different source-
+size systems at given T = 2 MeV and ρ = 0.6ρ0.
+2
+3
+4
+5
+6
+7
+4
+8
+12
+16
+20
+2
+3
+4
+5
+6
+7
+(a) A=36 Z=15
+r0 (fm)
+(b) A=129 Z=54
+ ρ = 0.2 ρ0 
+ ρ = 0.4 ρ0
+ ρ = 0.6 ρ0 
+ ρ = 0.8 ρ0
+ ρ = 1.0 ρ0 
+ ρ = 1.2 ρ0
+T (MeV)
+FIG. 8.
+Gaussian source radius as a function of temperature
+at different densities (ρ = 0.2ρ0, 0.4ρ0, 0.6ρ0, 0.8ρ0, 1.0ρ0,
+1.2ρ0) for a fixed source size. Panel (a) and (b) correspond to
+the smaller source size with (A = 36, Z = 15) and the larger
+source size with (A = 129, Z = 54), respectively.
+a fixed system size could be explained by the decreasing
+of the coordinate space as shown in Fig. 1 (a). And the
+small Cpp(q) strength at temperature higher than 8 MeV
+could be caused by the large momentum space compared
+with lower temperatures as shown in Fig. 1 (d-f). The
+decrease of the Cpp(q) strength with the increase of the
+system size for a fixed density could also be explained by
+the increasing of the coordinate space as shown in Fig. 5
+(g). Thus it is concluded that the phase space size for
+the emitted nucleons have strong effect on strength of the
+two-particle momentum correlation function, which can
+also be seen in the extracted Gaussian radii as shown in
+Fig. 8.
+IV.
+SUMMARY
+In summary, the two-particle momentum correlation
+functions for single excited sources are investigated using
+the Lednick´y and Lyuboshitz analytical formalism with
+the phase-space information at the freeze-out stage for
+different initial temperatures and densities in a frame-
+work of the ThIQMD transport approach. We mainly
+performed a series of studies focusing on the varied ef-
+fects of source temperature, density and system-size on
+the two-particle momentum correlation functions. The
+results reflect that the shape of the two-proton momen-
+
+8
+2
+3
+4
+5
+6
+7
+2
+3
+4
+5
+6
+7
+4
+8
+12
+16
+20
+2
+3
+4
+5
+6
+7
+0.2 0.4 0.6 0.8 1.0 1.2
+(a) ρ = 0.2 ρ0
+ A = 36    
+ A = 52 
+ A = 80    
+ A = 96 
+ A = 100 
+ A = 112
+ A = 129
+(d) T = 2 MeV
+(c) ρ = 1.0 ρ0
+(b) ρ = 0.6 ρ0
+r0 (fm)
+(e) T = 6 MeV
+(f) T = 10 MeV 
+T (MeV)
+ρ / ρ0
+FIG. 9.
+Gaussian source radius as a function of temperature
+or density at different source-size systems.
+Left and right
+columns correspond to r0 at different densities, i.e ρ = 0.2 ρ0
+(a), 0.6 ρ0 (b), and 1.0 ρ0 (c) as well as different temperatures,
+i.e. T = 2 (d), 6 (e), and 10 (f) MeV , respectively.
+tum correlation function is in accordance with the previ-
+ous experimental data in heavy-ion collisions [68].
+At
+the same time, the trend of the relationship between
+the two-proton momentum correlation and system-size
+is consistent with previous simulations [37, 38, 69]. At
+low source-temperature, the larger density makes the
+two-particle momentum correlation stronger. However,
+at higher source temperature, the effect becomes almost
+disappear. Both proton-proton correlations and neutron-
+neutron correlations have the similar responses to tem-
+perature and density.
+This work also shows that the
+emission source is not much influenced by density above
+a certain temperature for a single excited source. In the
+same way, the emission source are softly influenced by
+temperature below a given density for a single excited
+source. In one word, the dependence of the two-particle
+momentum correlation function on the source tempera-
+ture, density and system size could be explained by the
+change of the coordinate and/or momentum phase space
+sizes. In the end, the Gaussian radii are extracted to ex-
+plore the emission source sizes in single excited systems.
+Gaussian radii become larger in the larger systems. The
+dependence of the extracted Gaussian radius on source-
+temperature and density is consistent with behavior of
+the two-proton momentum correlation function as dis-
+cussed in the texts.
+ACKNOWLEDGMENTS
+This work was supported in part by the National Nat-
+ural Science Foundation of China under contract Nos.
+11890710, 11890714, 11875066, 11925502, 11961141003,
+11935001, 12147101 and 12047514, the Strategic Pri-
+ority Research Program of CAS under Grant No.
+XDB34000000, National Key R&D Program of China un-
+der Grant No. 2016YFE0100900 and 2018YFE0104600,
+Guangdong Major Project of Basic and Applied Basic
+Research No. 2020B0301030008, and the China PostDoc-
+toral Science Foundation under Grant No. 2020M681140.
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diff --git a/6NE1T4oBgHgl3EQfBQJe/content/tmp_files/load_file.txt b/6NE1T4oBgHgl3EQfBQJe/content/tmp_files/load_file.txt
new file mode 100644
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf,len=937
+page_content='Temperature and density effects on the two-nucleon momentum correlation function  from excited single nuclei  Ting-Ting Wang(王婷婷),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
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+page_content=' 2 De-Qing Fang(方德清),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2 and Huan-Ling Liu(刘焕玲)3  1Key Laboratory of Nuclear Physics and Ion-Beam Application (MOE),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Institute of Modern Physics,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Fudan University,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Shanghai 200433,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' China  2Shanghai Research Center for Theoretical Nuclear Physics，' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='NSFC and Fudan University,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Shanghai 200438,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' China  3Shanghai Institute of Applied Physics,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Chinese Academy of Sciences,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Shanghai 201800,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' China  (Dated: January 10,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2023)  Two-nucleon momentum correlation functions are investigated for different single thermal sources  at given initial temperature (T) and density (ρ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' To this end, the space-time evolutions of various  single excited nuclei at T = 1 − 20 MeV and ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 - 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0 are simulated by using the ther-  mal isospin-dependent quantum molecular dynamics (ThIQMD) model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Momentum correlation  functions of identical proton-pairs (Cpp(q)) or neutron-pairs (Cnn(q)) at small relative momenta  are calculated by Lednick´y and Lyuboshitz analytical method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The results illustrate that Cpp(q)  and Cnn(q) are sensitive to the source size (A) at lower T or higher ρ, but almost not at higher  T or lower ρ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' And the sensitivities become stronger for smaller source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Moreover, the T, ρ and A  dependencies of the Gaussian source radii are also extracted by fitting the two-proton momentum  correlation functions, and the results are consistent with the above conclusions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  INTRODUCTION  Properties of nuclear matter is one of the most in-  teresting topics in heavy-ion physics  [1–4] and lots of  works have been done around zero temperature, includ-  ing the nuclear equation of state (EOS).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' However, the  studies on properties of nuclear matter at finite tem-  peratures are relatively limited.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Many previous works  mainly focus on the temperature dependence of hot nu-  clear matter and the nuclear liquid-gas phase transition  (LGPT) [5–14], the ratio between shear viscosity over  entropy density (η/s) [15–19], as well as the nuclear gi-  ant dipole resonance [20–22] etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Among above works,  the relationship between the phase transition tempera-  ture and the source size has been investigated [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In  Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' [5], the finite-size scaling effects on nuclear liquid-  gas phase transition probes are investigated by study-  ing de-excitation processes of the thermal sources by the  isospin-dependent quantum molecular dynamics model  (IQMD).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Several probes, including the total multiplicity  derivative, second moment parameter, intermediate mass  fragment multiplicity, Fisher,s power-law exponent as  well as nuclear Zipf ,s law exponent of Ma [9] were ex-  plored, and the phase transition temperatures were then  obtained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Recently, the deep neural network has also  been used to determine the nuclear liquid gas phase tran-  sition [23] and to estimate the temperature of excited  nuclei by the charge multiplicity distribution of emitted  fragments [24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The latter work proposed that the charge  multiplicity distribution can be used as a thermometer of  heavy-ion collisions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Considering that the intermediate-state at high tem-  perature and density in the evolution process of nuclear  reactions cannot be directly measured, one always ex-  plore properties of nuclear matter and the dynamical  description of heavy-ion collisions through the analysis  of the final-state products.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  As well known, the two-  particle momentum correlation function in the final-state  has been extensively used as a probe of the space-time  properties and characteristics of the emission source [25–  27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The two-proton momentum correlation function has  been explored systematically by a lot of experiments as  well as different models, several reviews can be found  in Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' [28–31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In various studies on the momentum  correlation function, impacts of the impact parameter,  the total momentum of nucleon pairs, the isospin of the  emission source, the nuclear symmetry energy, the nu-  clear equation of state (EOS) as well as the in-medium  nucleon-nucleon cross section have been discussed in lit-  erature [32–38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Even more, nuclear structure effects  were also carefully investigated, such as the effects from  binding energy and separation energy of the nucleus [39],  density distribution of valence neutrons in neutron-rich  nuclei [40], as well as high momentum tail of the nucleon-  momentum distribution [41] etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Two-proton momentum  correlation function was also constructed in few-body re-  actions as well as α-clustered nucleus induced collisions  [42–46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In addition, momentum correlation function be-  tween two light charged particles also offers a unique  tool to investigate dynamical expansion of the reaction  zone [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Here we extend the momentum correlation method  of final-state interaction to study the time-spatial infor-  mation of the finite-temperature nuclear systems which  have different initial density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The purpose of the present  paper is to systematically investigate the relationship  between two-particle momentum correlation functions  and system parameters, such as the source-temperature,  density as well as system-size in a framework of the  thermal isospin-dependent quantum molecular dynamics  (ThIQMD) model  [5, 14, 17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In addition, the Gaus-  sian source radii are quantitatively extracted by assump-  tion of Gaussian source fits to the momentum correla-  tion function distributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In this article, the evolution  process of excited nuclear sources at given initial tem-  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='02849v1  [nucl-th]  7 Jan 2023  2  peratures varying from 1 MeV to 20 MeV are studied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The present work selects six different nuclear systems  with similar ratio of neutron to proton numbers, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=',  N/Z ∼ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='3, which include (A, Z) = (36, 15), (52, 24),  (80, 33), (100, 45), (112, 50), and (129, 54) nuclei.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Then,  Lednick´y-Lyuboshitz theoretical approach [47] is applied  for calculating two-particle momentum correlation func-  tions which are constructed based on phase-space infor-  mation from the evolution process of single excited nu-  clear sources by the ThIQMD model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The rest of this article is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In Sec-  tion II, we firstly describe the thermal isospin-dependent  quantum molecular dynamics model [14, 17], then briefly  introduce the momentum correlation technique using  Lednick´y and Lyuboshitz analytical formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In Sec-  tion III, we show the results of the ThIQMD plus  the LL method for the source-temperature dependence  of two-particle momentum correlation function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The  two-particle momentum correlation functions of differ-  ent system-sizes at different initial densities are sys-  tematically discussed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The detailed analysis of the ex-  tracted Gaussian source radii are presented under differ-  ent source-temperature and density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Furthermore, the  momentum correlation function of two-neutron is also  analyzed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Finally, Section IV gives a summary of the  paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  MODELS AND FORMALISM  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  THE ThIQMD MODEL  In this paper, the thermal isospin-dependent Quan-  tum Molecular Dynamics transport model is used as  the event generator, which has been applied success-  fully to study the LGPT [5, 24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In the following  discussion, we introduce this model briefly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  As well  known, isospin-dependent Quantum Molecular Dynam-  ics (IQMD) model was used to describe the collision  process between two nuclei.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The Quantum Molecular  Dynamics transport model is a n-body transport theory,  which describes heavy-ion reaction dynamics from inter-  mediate to relativistic energies [48–51].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In the present  work, we use a single excited source in the ThIQMD  which is different from the traditional IQMD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Usually,  the ground state of the initial nucleus is considered to be  T = 0 MeV in the traditional IQMD model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' However,  the ThIQMD model developed by Fang, Ma, and Zhou  in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' [17] is used to simulate single thermal source at  different temperatures and densities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The main parts of QMD transport model include the  following issues: the initialization of the projectile and  the target, nucleon propagation under the effective po-  tential, the collisions between the nucleons in the nuclear  medium and the Pauli blocking effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In the ThIQMD,  instead of using the Fermi-Dirac distribution for T = 0  MeV with the nucleon’s maximum momentum limited  by P i  F (⃗r) = ℏ  �  3π2ρi(⃗r)  �1/3, the initial momentum of nu-  cleons is sampled by the Fermi-Dirac distribution at finite  temperature:  n (ek) =  g (ek)  e  ek−µi  T  + 1  ,  (1)  where the kinetic energy ek =  p2  2m, p and m is the mo-  mentum and mass of the nucleon, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' g (ek) =  V  2π2  � 2m  ℏ2  � 3  2 √ek represents the state density with the vol-  ume of the source V = 4  3πr3 where r = rV A  1  3 (rV is a  parameter to adjust the initial density).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In addition, the chemical potential µi is determined by  the following equation:  1  2π2  �2m  ℏ2  � 3  2 � ∞  0  √ek  e  ek−µi  T  + 1  dek = ρi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  (2)  where i = n or p refer to the neutron or proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In the ThIQMD model, the interaction potential is  also represented by the form as follows:  U = USky + UCoul + UY uk + USym + UMDI,  (3)  where USky, UCoul, UY uk, USym, and UMDI are the  density-dependent Skyrme potential, the Coulomb po-  tential, the surface Yukawa potential, the isospin asym-  metry potential, and the momentum-dependent interac-  tion, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Among these potentials, the Skyrme  potential, the Coulomb potential and the momentum-  dependent interaction can be written as follows:  USky = α( ρ  ρ0  ) + β( ρ  ρ0  )γ,  (4)  where ρ and ρ0 are total nucleon density and its normal  value at the ground state, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='16 fm−3, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The above parameters α, β, and γ with an incompress-  ibility parameter K are related to the nuclear equation  of state [52–58].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  USym = Csym  (ρn − ρp)  ρ0  τz,  (5)  UCoul = 1  2 (1 − τz) Vc,  (6)  where ρn and ρp are neutron and proton densities, re-  spectively, τz is the z-th component of the isospin degree  of freedom for the nucleon, which equals 1 or −1 for a  neutron or proton, respectively, and Csym is the symme-  try energy coefficient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' UCoul is the Coulomb potential  where Vc is its parameter for protons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  UMDI = δ · ln2 �  ϵ · (∆p)2 + 1  �  ρ  ρ0  ,  (7)  where ∆p is the relative momentum, δ and ϵ can be found  in Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' [48, 49].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Their values of the above potential  parameters are all listed in Table I:  3  TABLE I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The value of the interaction potential parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  α  β  γ  K  δ  ϵ  (MeV ) (MeV )  (MeV ) (MeV ) ((GeV/c)−2)  −390.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='1  320.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='14  200  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='57  500  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  LEDNICK ´Y AND LYUBOSHITZ  ANALYTICAL FORMALISM  Next, we briefly review the method for the two-particle  momentum correlation function proposed by Lednick´y  and Lyuboshitz [47, 59, 60].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The momentum correlation  technique in nuclear collisions is based on the principle  as follows: when they are emitted at small relative mo-  mentum, the two-particle momentum correlation is deter-  mined by the space-time characteristics of the production  processes owing to the effects of quantum statistics (QS)  and final-state interactions (FSI) [61, 62].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Therefore,  the two-particle momentum correlation function can be  expressed through a square of the symmetrizied Bethe-  Salpeter amplitude averaging over the four coordinates  of the emitted particles and the total spin of the two-  particle system, which represents the continuous spec-  trum of the two-particle state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In this theoretical approach, the final-state interactions  of the particle pairs is assumed independent in the pro-  duction process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' According to the conditions in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' [63],  the correlation function of two particles can be written  as the expression:  C (k∗) =  �  S (r∗, k∗) |Ψk∗ (r∗)|2 d4r∗  �  S (r∗, k∗) d4r∗  ,  (8)  where r∗ = x1 − x2 is the relative distance of the two  particles in the pair rest frame (PRF) at their kinetic  freeze-out, k∗ is half of the relative momentum between  two particles in the PRF, S (r∗, k∗) is the probability to  emit a particle pair with given r∗ and k∗, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', the source  emission function, and Ψk∗ (r∗) is the equal-time (t∗ = 0)  reduced Bethe-Salpeter amplitude which can be approx-  imated by the outer solution of the scattering problem in  the PRF [64, 65].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' This approximation is valid on condi-  tion |t∗| ≪ m (r∗)2, which is well fulfilled for sufficiently  heavy particles like protons or kaons and reasonably ful-  filled even for pions [59].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In the above limit, the asymp-  totic solution of the wave function of the two charged  particles approximately takes the expression:  Ψk∗ (r∗) = eiδc�  Ac (λ)×  �  e−ik∗r∗F (−iλ, 1, iξ) + fc (k∗)  ˜G (ρ, λ)  r∗  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  (9)  In the above equation, δc = arg Γ (1 + iλ) is the Coulomb  s-wave phase shift with λ = (k∗ac)−1 where ac is the two-  particle Bohr radius, Ac (λ) = 2πλ [exp (2πλ) − 1]−1 is  the Coulomb penetration factor, and its positive (neg-  ative) value corresponds to the repulsion (attraction).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  ˜G (ρ, λ) =  �  Ac (λ) [G0 (ρ, λ) + iF0 (ρ, λ)] is a combina-  tion of regular (F0) and singular (G0) s-wave Coulomb  functions [59, 60].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' F (−iλ, 1, iξ) = 1 + (−iλ) (iξ) /1!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 +  (−iλ) (−iλ + 1) (iξ)2 /2!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 + · · · is the confluent hyperge-  ometric function with ξ = k∗r∗ + ρ, ρ = k∗r∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  fc (k∗) =  �  Kc (k∗) − 2  ac  h (λ) − ik∗Ac (λ)  �−1  (10)  is the s-wave scattering amplitude renormalizied by  the long-range Coulomb interaction,  with h (λ)  =  λ2 �∞  n=1  �  n  �  n2 + λ2��−1−C −ln [λ] where C = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5772 is  the Euler constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Kc (k∗) =  1  f0 + 1  2d0k∗2 +Pk∗4 +· · · is  the effective range function, where d0 is the effective ra-  dius of the strong interaction, f0 is the scattering length  and P is the shape parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The parameters of the  effective range function are important parameters char-  acterizing the essential properties of the FSI, and can  be extracted from the correlation function measured ex-  perimentally [38, 65–67].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  For n-n momentum correlation functions which include  uncharged particle, only the short-range particle inter-  action works.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' For p-p momentum correlation functions,  both the Coulomb interaction and the short-range parti-  cle interaction dominated by the s-wave interaction are  taken into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  ANALYSIS AND DISCUSSION  Within  the  framework  of  the  thermal  isospin-  dependent  quantum  molecular  dynamics  model  [5,  14, 17], the two-particle momentum correlation func-  tions are calculated by using the phase-space infor-  mation from the freeze-out stage of the excited nu-  clear source at an initial temperature varying from 1  MeV  to 20 MeV  and/or density varying from ρ =  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0 to 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  This work performs calculations for  thermal source systems with different mass including  (A, Z)  =  (36, 15), (52, 24), (80, 33), (100, 45), (112, 50),  and (129, 54).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  We firstly calculated the proton-proton momentum  correlation function Cpp(q) for finite-size systems at tem-  peratures ranging from 1 to 20 MeV .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1, the  results of Cpp(q) for temperature of 2, 4, 6, 8, 10 and  12 MeV at different values of density (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0 - 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0)  are presented.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The proton-proton momentum correla-  tion function exhibits a peak at relative momentum q =  20 MeV/c, which is due to the strong final-state s-wave  attraction together with the suppression at lower rela-  tive momentum as a result of Coulomb repulsion and the  antisymmetrization wave function between two protons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The shape of the two-proton momentum correlation func-  tions is consistent with many previous experimental data  in heavy-ion collisions, eg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' [68].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' For protons which  are emitted from the lower temperature (T < 8 MeV )  source in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1 (a)-(c), the general trend is very similar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The figure shows that Cpp(q) increases as ρ increases for  4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  20  40  60  80  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  20  40  60  80  (a) T = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  Cpp(q)  (d) T = 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (b) T = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (e) T = 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (c) T = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (f) T = 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  q (MeV/c)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The proton-proton momentum correlation function  (Cpp(q)) at different densities (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8ρ0,  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0ρ0, and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0) for the smaller nucleus (A=36, Z=15) with  fixed source-temperatures T = 2 MeV (a), 4 MeV (b), 6  MeV (c), 8 MeV (d), 10 MeV (e) and 12 MeV (f), respec-  tively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The freeze-out time is taken to be 200 fm/c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  fixed T (T < 8 MeV ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The increase of the density in-  dicates that the geometrical size becomes smaller for a  source with fixed neutrons and protons, which makes the  strength of the momentum correlation function stronger.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Finally, the p-p momentum correlation function becomes  almost one at q > 60 MeV/c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  For larger T (T > 8  MeV ) in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1 (d)-(f), the difference of Cpp(q) between  different densities becomes smaller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  From Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1, it is  found that the Cpp(q) almost keep the same above T = 8  MeV for different densities and the p-p momentum cor-  relation function becomes almost unique above approx-  imately q = 30 MeV/c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  It indicates that the emitted  proton is not affected by the change of density when the  source temperature beyond certain value (T ≈ 8 MeV in  present work).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In order to understand which one of the  two factors (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', temperature and density) has larger in-  fluence, the two-particle momentum correlation in fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2  is plotted by exchanging of the two input parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  From fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2, we can intuitively observe dependence of the  two-particle momentum correlation on the source tem-  perature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The dependence of Cpp(q) on the source tem-  perature is stronger than on density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  In other words,  the Cpp(q) is more sensitive to T than to density ρ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  20  40  60  80  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  20  40  60  80  (d) ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0  (a) ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  Τ =  2 MeV  Τ =  8 MeV  Τ =  4 MeV  Τ =  10 MeV  Τ =  6 MeV  Τ =  12 MeV  Cpp(q)  (c) ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  (b) ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0  (f) ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  (e) ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  q (MeV/c)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Similar to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1, but at different source-  temperatures (T = 2, 4, 6, 8, 10 and 12 MeV ) with different  fixed densities, namely ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0 (a), 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0 (b), 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0 (c),  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0 (d), 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0 (e), and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0 (f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  addition, for larger ρ from fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2 (a) to (f), the differ-  ence of Cpp(q) between different densities becomes bigger.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Next, we explore whether the phenomenon exists in mo-  mentum correlation functions for the uncharged-particle  pairs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 3 presents the neutron-neutron momentum  correlation functions (Cnn(q)) for temperature of 2, 4,  6, 8, 10 and 12 MeV at different values of density, re-  spectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' For neutron-neutron momentum correlation  function, it peaks at q ≈ 0 MeV/c caused by the s-wave  attraction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Although the Cnn(q) has different shape com-  pared with the p-p momentum correlation function, it has  the similar dependence on the source temperature and  density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The similar trend in Cpp(q) and Cnn(q) shows  the close emission mechanism in the evolution process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 4 shows the results of a larger system at differ-  ent source-temperature and density, and a similar be-  havior of Cpp(q) is demonstrated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' We also observe that  the proton-proton momentum correlation in larger-size  system ((A, Z) = (129, 54)) in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 4 becomes weaker  in comparison with the smaller-size source ((A, Z) =  (36, 15)) in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In view of the above phenomenon,  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 5 describes the relationship between system-size and  momentum correlation function in more details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The  decreasing of Cpp(q) as the system-size increasing for a  fixed value of T or ρ can be clearly seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 5 (g),  5  2  4  6  8  10  12  14  2  4  6  8  10  12  14  20  40  60  80  2  4  6  8  10  12  14  20  40  60  80  (b) T = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (a) T = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  (d) T = 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (e) T = 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (c) T = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  q (MeV/c)  Cnn(q)  (f) T = 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The neutron-neutron (n-n) momentum correlation  functions (Cnn(q)) in the same conditions as Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  which is consistent with the previous results of Gaussian  source [37, 38, 69].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 5 (a)-(i), with larger temper-  ature or lower density, the difference of Cpp(q) between  different T or ρ becomes smaller, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The Gaus-  sian source radii are extracted for further discussion later  in this article.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  From the above plots, we can extract Cmax(q), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=',  the maximum value of Cpp(q) as well as the full width at  half maximum (FWHM) of Cpp(q) distribution, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' at  Cpp(q) = [Cmax(q)−1]/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The source-temperature T de-  pendence of Cmax(q) and FWHM for the proton-proton  momentum correlation function with different density are  given in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' As shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 6 (a) and (b), both  Cmax(q) and FWHM decrease gradually with the in-  creasing of T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In addition, both of them increase grad-  ually with density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  At high temperature, the change  of Cmax(q) and FWHM is very small and not plotted  in the figure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Of course, the behavior of the Cmax(q)  and FWHM with T and ρ can also be clearly seen in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2, and the increasing of Cmax(q) and FWHM are  generally inversely proportional to Gaussian radius r0 as  shown later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Similarly, the system-size A dependence  of Cmax(q) and FWHM for the proton-proton momen-  tum correlation function at T = 2MeV and ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6ρ0  is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The dependence of Cmax(q) and  FWHM on system-size A is quite similar to the temper-  ature dependence in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The Cmax(q) and FWHM  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  20  40  60  80  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  20  40  60  80  (a) T = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  (d) T = 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (b) T = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (e) T = 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (c) T = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  (f) T = 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 MeV  Cpp(q)  q (MeV/c)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Same to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1, but for a larger system (A=129,  Z=54).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  values become smaller for larger systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 8 shows the source-temperature, density, and  system-size dependence of Gaussian radii extracted from  two-particle momentum correlation functions,  where  panels (a) and (b) are results with the smaller source  size and the larger source size, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The radii  are extracted by a Gaussian source assumption, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=',  S(r) ≈ exp[−r2/(4r2  0)], where r0 is the Gaussian source  radius from the proton-proton momentum correlation  functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The theoretical calculations for Cpp(q) was  performed by using the Lednick´y and Lyuboshitz an-  alytical method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The best fitting radius is judged by  finding the minimum of the reduced chi-square between  the ThIQMD calculations and the Gaussian source as-  sumption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Since the effect of the strong FSI scales as  fc (k∗) /r∗ in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' (9), one may read the sensitivity of  the correlation function to the temperature T, density  ρ and atomic number A from their effects on the Gaus-  sian radius r0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' One may observe a linear dependence on  these parameters up to T ≈ 8 MeV and then a lost of  sensitivity in a plateau region at higher temperatures in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' As the density decreases, the decreasing speed of  the Gaussian radius of the small system is larger than  that of the larger system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 9 shows the Gaussian ra-  dius of the different system-size varies with the temper-  ature in panels (a)-(c) or density in panels (d)-(f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The  Gaussian source radius is consistent with the system-size,  6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  40  80  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  40  80  40  80  (a)  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0  T = 6 MeV  T = 4 MeV  A = 36  A = 52  A = 80  A = 96  A = 100  A = 112  A = 129  T = 2 MeV  (b)  (c)  (d)  (g)  (e)  (f)  (h)  (i)  Cpp(q)  q (MeV/c)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Cpp(q) of different source size systems at fixed temperatures (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', from left column to right column, they correspond  to T = 2, 4 and 6 MeV , respectively) or fixed densities (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', from top row to bottom row, they correspond to ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6ρ0,  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0ρ0, respectively).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=', at higher temperature or larger density, the differ-  ences of Gaussian source between different system sizes  are bigger in the low density and low temperature region,  but the difference in opposite conditions almost disap-  pear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In other words, the sensitivity of the source radii  to the system size seem to be different in the different  regions of temperatures and densities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' For example, the  sensitivity is better in the region of lower T and higher ρ  (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 9(b) and (c)), or it is better in the higher T region  for the lower ρ (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 9(a)), or it is better in the higher ρ  region for the lower T (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 9(d)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  From the above discussion, it is demonstrated that  the strength of the two-particle momentum correlation  function is affected by the source temperature, density  and system size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The two-particle momentum correlation  function strength is larger for a single source with lower  temperature, higher density or smaller mass number as  shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1-5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Otherwise, the strength becomes  smaller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' To some extents, the strong correlation between  two particles is mainly caused by the closed position of  each other in phase space in both coordinate and momen-  tum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Varying only one in the three condition parameters  (temperature, density and system size), lower temper-  ature means smaller momentum space, higher density  means smaller coordinate space and small system size  also mean smaller coordinate space to keep fixed den-  sity compared with large system size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  The dependen-  cies of the two-particle momentum correlation function  strength on the source temperature, density and system  size could be explained by the change of the phase space  sizes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Two particles emitted from small phase space will  have strong correlation and those from large phase space  will have weak correlation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' For example, the increase of  the Cpp(q) strength with the increase of the density for  7  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  2  3  4  5  6  4  6  8  10  12  (a)  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  Cmax(q)  (b)  FWHM (Mev/c)  T (MeV)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Source-temperature T dependencies of Cmax(q)  (a) and of FWHM (b) of Cpp(q) distributions at different  densities (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0 - 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0) for the (A = 35, Z = 16) system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8  40  60  80  100  120  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='5  (a)  y = b+a*x    value  a  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0055  b  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0358  Cmax(q)  Cmax(q)  Fitting curve  (b)  y = b+a*x    value  a  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='022  b  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='913  A  FWHM (Mev/c)  FWHM  Fitting curve  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Cmax(q) (a) and FWHM (b) for different source-  size systems at given T = 2 MeV and ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6ρ0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  2  3  4  5  6  7  4  8  12  16  20  2  3  4  5  6  7  (a) A=36 Z=15  r0 (fm)  (b) A=129 Z=54  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  T (MeV)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Gaussian source radius as a function of temperature  at different densities (ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6ρ0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8ρ0, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0ρ0,  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2ρ0) for a fixed source size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Panel (a) and (b) correspond to  the smaller source size with (A = 36, Z = 15) and the larger  source size with (A = 129, Z = 54), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  a fixed system size could be explained by the decreasing  of the coordinate space as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1 (a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' And the  small Cpp(q) strength at temperature higher than 8 MeV  could be caused by the large momentum space compared  with lower temperatures as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 1 (d-f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The  decrease of the Cpp(q) strength with the increase of the  system size for a fixed density could also be explained by  the increasing of the coordinate space as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 5  (g).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Thus it is concluded that the phase space size for  the emitted nucleons have strong effect on strength of the  two-particle momentum correlation function, which can  also be seen in the extracted Gaussian radii as shown in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  SUMMARY  In summary, the two-particle momentum correlation  functions for single excited sources are investigated using  the Lednick´y and Lyuboshitz analytical formalism with  the phase-space information at the freeze-out stage for  different initial temperatures and densities in a frame-  work of the ThIQMD transport approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' We mainly  performed a series of studies focusing on the varied ef-  fects of source temperature, density and system-size on  the two-particle momentum correlation functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The  results reflect that the shape of the two-proton momen-  8  2  3  4  5  6  7  2  3  4  5  6  7  4  8  12  16  20  2  3  4  5  6  7  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='4 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='8 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2  (a) ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  A = 36  A = 52  A = 80  A = 96  A = 100  A = 112  A = 129  (d) T = 2 MeV  (c) ρ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0  (b) ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0  r0 (fm)  (e) T = 6 MeV  (f) T = 10 MeV  T (MeV)  ρ / ρ0  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Gaussian source radius as a function of temperature  or density at different source-size systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Left and right  columns correspond to r0 at different densities, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e ρ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='2 ρ0  (a), 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='6 ρ0 (b), and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='0 ρ0 (c) as well as different temperatures,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' T = 2 (d), 6 (e), and 10 (f) MeV , respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  tum correlation function is in accordance with the previ-  ous experimental data in heavy-ion collisions [68].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  At  the same time, the trend of the relationship between  the two-proton momentum correlation and system-size  is consistent with previous simulations [37, 38, 69].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' At  low source-temperature, the larger density makes the  two-particle momentum correlation stronger.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' However,  at higher source temperature, the effect becomes almost  disappear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Both proton-proton correlations and neutron-  neutron correlations have the similar responses to tem-  perature and density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  This work also shows that the  emission source is not much influenced by density above  a certain temperature for a single excited source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In the  same way, the emission source are softly influenced by  temperature below a given density for a single excited  source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In one word, the dependence of the two-particle  momentum correlation function on the source tempera-  ture, density and system size could be explained by the  change of the coordinate and/or momentum phase space  sizes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' In the end, the Gaussian radii are extracted to ex-  plore the emission source sizes in single excited systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Gaussian radii become larger in the larger systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' The  dependence of the extracted Gaussian radius on source-  temperature and density is consistent with behavior of  the two-proton momentum correlation function as dis-  cussed in the texts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  ACKNOWLEDGMENTS  This work was supported in part by the National Nat-  ural Science Foundation of China under contract Nos.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  11890710, 11890714, 11875066, 11925502, 11961141003,  11935001, 12147101 and 12047514, the Strategic Pri-  ority Research Program of CAS under Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  XDB34000000, National Key R&D Program of China un-  der Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2016YFE0100900 and 2018YFE0104600,  Guangdong Major Project of Basic and Applied Basic  Research No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2020B0301030008, and the China PostDoc-  toral Science Foundation under Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 2020M681140.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  [1] G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Giuliani, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Zheng, and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Bonasera, Prog.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content='  Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
+page_content=' 76, 116 (2014).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
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+page_content=' Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/6NE1T4oBgHgl3EQfBQJe/content/2301.02849v1.pdf'}
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+Flagged observation analyses as a tool for scoping and communication in 
+Integrated Ecosystem Assessments   
+ 
+Solvang, Hiroko Kato 
+Institute of Marine Research, P.O. Box 1870 Nordnes, N-5817 Bergen, Norway 
+hirokos@hi.no 
+Arneberg, Per 
+Institute of Marine Research, Fram Centre, P.O. Box 6606, 9296 Langnes, Norway 
+perab@hi.no 
+ 
+Abstract 
+Working groups for integrated ecosystem assessments are often challenged with understanding and 
+assessing recent change in ecosystems. As a basis for this, the groups typically have at their disposal 
+many time series and will often need to prioritize which ones to follow up for closer analyses and 
+assessment. Here we provide a procedure termed Flagged observation analyses that can be applied to 
+all the available time series to help identifying time series that should be prioritized. The statistical 
+procedure first applies a structural time series model including a stochastic trend model to the data to 
+estimate the long-term trend. The model adopts a state space representation, and the trend component 
+is estimated by a Kalman filter algorithm. The algorithm obtains one- or more-years-ahead prediction 
+values using all past information from the data. Thus, depending on the number of years the investigator 
+wants to consider as “the most recent”, the expected trend for these years is estimated through the 
+statistical procedure by using only information from the years prior to them. Forecast bands are 
+estimated around the predicted trends for the recent years, and in the final step, an assessment is made 
+on the extent to which observations from the most recent years fall outside these forecast bands. Those 
+that do, may be identified as flagged observations. A procedure is also presented for assessing whether 
+the combined information from all of the most recent observations form a pattern that deviates from the 
+predicted trend and thus represents an unexpected tendency that may be flagged. In addition to form the 
+basis for identifying time series that should be prioritized in an integrated ecosystem assessment, 
+flagged observations can provide the basis for communicating with managers and stakeholders about 
+recent ecosystem change. Applications of the framework are illustrated with two worked examples. 
+ 
+Keywords: Trend estimation, Kalman filter, Prediction, Forecast band, Stakeholder, Climate change
+ 
+ 
+ 
+Introduction  
+Against a background of increasing impact from climate change and other anthropogenic drivers, 
+causing elevated rates of change in marine ecosystems [1-6] leading to patterns of variability beyond 
+the range of the Holocene [7-12], ecosystem-based management (EBM) is increasingly identified as a 
+needed framework for management of marine socio-ecological systems [13]. Integrated ecosystem 
+
+assessments (IEA) have been developed to provide the scientific basis for EBM [14], and numerous 
+groups of scientists working with IEA have been established, such as the regional IEA groups within 
+the International Council for the Exploration of the Sea (ICES, Walther and Möllmann (15)).  
+Among the core activities of IEA groups are analyses of time series to summarize changes that have 
+occurred in recent decades in ecosystems, highlight possible connections between physical, biological, 
+and human ecosystem components [14, 16]. Emphasis is put on keeping an open communication 
+management and stakeholders [13, 17, 18]. As the groups typically have at their disposal a large number 
+of time series [16, 19], it will often be necessary to prioritize a subset of them for more extensive 
+analyses and communication purposes [20, 21]. Prioritization should preferably be done using a 
+standardized framework applied to all time series. Here we present an approach which is based analyses 
+of patterns of recent change, where the aim is to identify time series in which the most recent values 
+deviate significantly from an expected trend, possibly indicating unexpected change. This should be of 
+high relevance for IEA groups, as they are often challenged with understanding and interpreting recent 
+change [14].  
+Our approach is based on first estimating trends of time series before assessing whether the most recent 
+observations deviate significantly from these trends. Since temporal changes in ecosystems can take the 
+form of long-term movements as well as short- or mid-term cyclic periods and noise components, 
+different definitions of trends have been used in marine IEAs [16]. In the field of statistical time series 
+analysis, the long-term movements are commonly classified as ‘trends’, while short- or mid-term cyclic 
+periods are not, due to the different assumptions about the statistical properties. When investigating a 
+trend in time series data, it can therefore be useful to separately identify non-stationary trends and 
+stationary cyclic components. This decomposition is performed by a framework called ‘structural time 
+series modelling’, which is using a state space representation where the state of each component is 
+estimated by the Kalman filter algorithm [22]. The concept is basically different from applying an 
+Autoregressive integrated moving average model to adjust with the aim of studying stationary processes 
+from nonstationary time series data [23]. 
+The Kalman filter algorithm can make one- or multistep-ahead predictions in the numerical procedure. 
+The numerical procedure introduced in this paper uses prediction values and forecast uncertainty bands 
+
+to assess the status of a recent observation, which determines whether the most recent observation 
+follows the prediction or deviates from it [24], thus giving an indication whether change that is 
+unexpected from the predicted trend, is occurring in the time series. We call the significant deviated 
+observations a “Flagged Observation (FO)” and the approach “Flagged Observation analysis”. The 
+interpretation of a FO is not equivalent to the types of early warning signals that have been proposed 
+with the aim of predicting critical transitions in marine populations or ecosystems [25, 26], nonlinear 
+ecological change [27] or early warning signs based on theoretical framework in social-ecological 
+networks [28], but is, as described above, a practical tool for IAE groups for prioritizing time series for 
+in depth analyses, communication and other purposes.  
+In this article, we first introduce the numerical procedure and then demonstrate two examples using 
+time series data for, respectively, the Atlantic Multi-decadal Oscillation (AMO) and the Norwegian Sea 
+ecosystem.  
+ 
+Statistical method  
+The statistical method includes first a procedure for trend estimation and second a procedure for flagged 
+observations analyses (FO analyses) based on multistep ahead prediction values. The output from these 
+analyses can be used to identify observations (for example years) that deviate significantly from the 
+expected trend. In addition, it can also be interesting to explore whether observations from the predicted 
+years together form a pattern where all are consecutively either above or below the predicted trend in a 
+way that is not expected. This is equivalent to asking whether there is an unexpected tendency for the 
+most recent years. The probability for observing this is smaller than the probability of detecting an FO 
+for a single observation. The details are given as below: 
+Trend estimation procedure 
+The observation model of a time series is given by 
+( )
+( )
+( ),
+1,
+,
+y n
+t n
+u n
+n
+N
+=
++
+=
+⋅⋅⋅
+   , 
+                                                                        (1) 
+
+where ( )
+t n is the trend component and ( )
+u n is the residual component at time step n, assuming Gaussian 
+white noise. In this article, we introduce a stochastic trend model given by a dth-order difference 
+equation model and a method for estimating the trend [29, 30]. 
+The stochastic differential trend model is defined by the dth-order difference equation, which was posed 
+as a smoothing problem by [31]. This model allows for more flexible trends than does the polynomial 
+regression model. The stochastic trend model for k variables is expressed in the following way: 
+( )
+( ),
+1,
+, ,
+i
+d
+i
+t
+t n
+v n
+i
+k
+∇
+=
+=
+⋅⋅⋅
+                                                                                                   (2) 
+where ∇ is a difference operator 
+( )
+( )
+(
+1)
+t n
+t n
+t n
+∇
+=
+−
+−
+ and 
+( )
+itv n  is assumed to be a white noise 
+sequence. If 
+1
+d =
+, ( )
+(
+1)
+t n
+t n
+≈
+−
+ and the trend is known as a random walk model. If 
+2
+d =
+, 
+( )
+2 (
+1)
+(
+2)
+0
+t n
+t n
+t n
+−
+−
++
+−
+≈
+ [29]. Provided that the variance of 
+( )
+itv n  is sufficiently small, ( )
+it n  
+yields a smooth trend. We choose the second order difference stochastic model to estimate trend in this 
+study. 
+The model can be represented in linear state space form [22, 29, 30], as 
+( )
+(
+1)
+( ),
+( )
+( )
+( ),
+z n
+Fz n
+Gv n
+y n
+Hz n
+w n
+=
+−
++
+=
++
+ 
+                                                                                                     (3) 
+where ( )
+z n is the state vector corresponding to ( )
+t n , ( )
+v n  is the system noise vector with mean 0 and 
+unknown variance 
+2
+v
+σ , F ,G , and H indicate integers or matrices, and 
+( )
+w n  is observation error 
+with mean 0 and unknown variance 
+2
+w
+σ . The state ( )
+z n corresponds to the trend component, which we 
+cannot directly observe from the data. The component is modelled by the dth-order differential equation 
+model. Corresponding to the above dth-order difference equation, when 
+1
+d =
+ in equation (2),  
+( )
+( )
+t n
+z n
+
+
+
+
+=
+, 
+1
+F
+G
+H
+=
+=
+=  . 
+ 
+When 
+2
+d =
+, the state vector and matrices are as follows: 
+
+( )
+( )
+(
+1)
+t n
+z n
+t n
+
+
+= 
+
+−
+
+ ,
+2
+1
+1
+0
+F
+−
+
+
+= 
+
+
+,
+1
+0
+G
+ 
+=  
+   , and 
+1
+0
+H
+ 
+=  
+   . 
+ 
+The observation error corresponds to ( )
+u n in equation (1) in this case. The trend component is estimated 
+with a Kalman filter, which is a powerful numerical algorithm that recursively operates the state 
+estimation, prediction and filtering:  
+prediction: 
+( |
+1)
+(
+1|
+1)
+( |
+1)
+(
+1|
+1)
+'
+z n n
+Fz n
+n
+V n n
+FV n
+n
+GQG
+−
+=
+−
+−
+−
+=
+−
+−
++
+                                                                                        (4) 
+filtering: 
+1
+( )
+( |
+1)
+'(
+( |
+1)
+'
+)
+( | )
+( |
+1)
+( ( )
+( |
+1))
+( | )
+(
+) ( |
+1)
+K n
+V n n
+H
+H V n n
+H
+R
+z n n
+z n n
+K y n
+H z n n
+V n n
+I
+K H V n n
+−
+=
+−
+−
++
+=
+−
++
+−
+−
+=
+−
+−
+                                                                          (5) 
+Here, ( |
+1)
+z n n −
+ and 
+( |
+1)
+V n n −
+ correspond to the conditional mean and conditional variance of the 
+state, R  is set as the observation error, and K  is called the Kalman gain. Setting the initial state 
+(
+)
+1| 0
+z
+ and variance 
+(
+)
+1| 0
+V
+as zero and the pre-determined system noise, the Kalman gain is 
+calculated by the initial variance and observation noise, and the filtering value (
+)
+1|1
+z
+ is obtained by 
+using observation 
+( )
+1
+y
+and the calculated gain from the filtering procedure (5). Then the next 
+prediction values (
+)
+2 |1
+z
+and 
+(
+)
+2 |1
+V
+are calcualted using (
+)
+1|1
+z
+ and 
+(
+)
+1|1
+V
+in the prediction 
+procedure (4). The iterative calculation procedure for the state is continued until n
+N
+=
+. Recursive 
+methods based on state space representations are known to be very efficient for calculating the 
+likelihood functions of discrete-time Gaussian proceeses. The state space model and the Kalman filter 
+provide an efficient method for the computation of the likelihood of the time series models [29]. In this 
+case, the trend model includes the parameter vector 
+2
+2
+( ,
+,
+)
+v
+w
+d
+θ
+σ
+σ
+=
+. The log-likelihood function ( )
+l θ  
+of the model is given by 
+
+1
+1
+1
+2
+( )
+log
+( ( ) |
+(
+1), ),
+1
+1
+log
+exp
+( )' ( )
+( )
+,
+2
+(2 ) det ( )
+N
+n
+N
+n
+l
+f y n
+Y n
+y n
+n
+y n
+n
+θ
+θ
+π
+=
+−
+=
+=
+−
+
+
+
+
+
+
+=
+−
+∆
+Σ
+∆
+
+
+
+
+
+
+Σ
+
+
+
+
+∑
+∑
+  
+where 
+(
+1)
+( (1), (2),
+, (
+1))
+Y n
+y
+y
+y n
+−
+=
+⋅⋅⋅
+−
+,
+( )
+( )
+( |
+1)
+y n
+y n
+Hz n n
+∆
+=
+−
+−
+, 
+and 
+2
+( )
+( )
+( |
+1)
+'( )
+w
+n
+H n V n n
+H n
+σ
+Σ
+=
+−
++
+. The flexibility of the estimated trend depends on 
+2
+v
+σ , which can be 
+determined by maximum likelihood within an arbitry variance range. The variance 
+2
+w
+σ  can be directly 
+set to the variance of the observation. If it is necessary to compare differernt order differential stochastic 
+model, the optimum differential order d is identified by the AIC [32] , which was formulated by the 
+maximum log-likelihood and number of parameters for d and the variances of system noise and 
+observation noise, given by AIC( )
+2 ( )
+2
+number of parameters
+c
+l θ
+= −
++
+×
+ . 
+After identifying the optimum trend model, the smoothed trend is estimated by a fixed-interval 
+smoother algorithm [33]: 
+1
+( )
+( | )
+' (
+1| )
+( |
+)
+( | )
+( )( (
+1|
+)
+(
+1| ))
+( |
+)
+( | )
+( )( (
+1|
+)
+(
+1| )) ( )'
+A n
+V n n F V n
+n
+z n N
+z n n
+A n
+z n
+N
+z n
+n
+V n N
+V n n
+A n V n
+N
+V n
+n A n
+−
+=
++
+=
++
++
+−
++
+=
++
++
+−
++
+ 
+In this study, we set the differential order as 
+2
+d =
+to obtain smooth trend for all time series data as 
+introduced in Kitagawa and Gersch (33) and take a procedure finding an optimum Q controlling 
+variability for the trend estimation within a range. 
+ 
+FO analysis by multistep-ahead prediction values 
+Using the Kalman filter algorithm directly, it can give only one-ahead prediction. However, it can be 
+expanded to multistep-ahead (j-ahead) prediction (
+1
+j >
+). Let us consider a relevant situation. With the 
+Kalman filter, one-ahead prediction for (
+)
+1
+z n +
+is obtained by (
+)
+1|
+z n
+n
++
+ and variance (
+)
+1|
+V n
+n
++
+. 
+If the data
+(
+)
+1
+y n +
+are not observed, the calculation is formally conducted by assuming 
+
+(
+)
+( )
+1
+Y n
+Y n
++
+=
+, 
+where 
+(
+)
+( )
+(1), (2),
+, ( )
+Y n
+y
+y
+y n
+=
+⋅⋅⋅
+. 
+Accordingly, 
+it 
+is 
+clear 
+that 
+(
+)
+(
+)
+1|
+1
+1|
+z n
+n
+z n
+n
++
++
+=
++
+and
+(
+)
+(
+)
+1|
+1
+1|
+V n
+n
+V n
+n
++
++
+=
++
+. Then, two-ahead prediction 
+(
+)
+2 |
+z n
+n
++
+and variance 
+(
+)
+2 |
+V n
+n
++
+ are obtained by (
+)
+1|
+z n
+n
++
+ and (
+)
+1|
+V n
+n
++
+. In general, we 
+assume ( )
+(
+1)
+(
+)
+Y n
+Y n
+Y n
+j
+=
++
+= ⋅⋅⋅ =
++
+ to obtain the j-ahead prediction, and the prediction step is 
+iteratively conducted j times. The algorithm used to predict states (
+)
+(
+)
+(
+)
+1 ,
+2 ,
+,
+z n
+z n
+z n
+j
++
++
+⋅⋅⋅
++
+, 
+based on the data ( )
+Y n  observed until time point n , is expressed as follows: 
+(
+)
+(
+)
+(
+)
+(
+)
+|
+1|
+,
+|
+1|
+'
+',
+1,
+, .
+z n
+i n
+Fz n
+i
+n
+V n
+i n
+FV n
+i
+n F
+GQG
+i
+j
++
+=
++ −
++
+=
++ −
++
+=
+⋅⋅⋅
+                         
+Now, let the mean and variance for the prediction (
+)
+y n
+j
++
+ of the data denote  
+(
+)
+( )
+(
+)
+E
+|
+y n
+j
+Y n
++
+and 
+(
+)
+( )
+(
+)
+Cov
+|
+y n
+j
+Y n
++
+, where 
+( )
+E ⋅  and 
+( )
+Cov ⋅  are notations for expectation and variance-
+covariance matrix (but in this study only variance because the data are univariate). Using the 
+observation equation (3), the mean of (
+)
+y n
+j
++
+ is expressed by 
+(
+)
+(
+)
+(
+)
+( )
+(
+)
+(
+)
+|
+=E
+|
+|
+.
+y n
+j n
+Hz n
+j
+w n
+j
+Y n
+Hz n
+j n
++
++
++
++
+=
++
+                                            (6) 
+The variance of (
+)
+y n
+j
++
+is given by 
+(
+)
+(
+)
+(
+)
+( )
+(
+)
+(
+)
+( )
+(
+)
+(
+)
+(
+)
+( )
+(
+)
+(
+)
+(
+)
+( )
+(
+)
+(
+)
+( )
+(
+)
+(
+)
+(
+)
+|
+=Cov
+|
+,
+Cov
+|
+'
+Cov
+,
+|
+Cov
+,
+|
+' Cov
+|
+,
+|
+'
+.
+d n
+j n
+Hz n
+j
+w n
+j
+Y n
+H
+z n
+j
+Y n
+H
+H
+z n
+j
+w n
+j
+Y n
+w n
+j
+z n
+j
+Y n
+H
+w n
+j
+Y n
+H V n
+j n H
+R n
+j
++
++
++
++
+=
++
++
++
++
++
++
++
++
++
+=
++
++
++
+       (7) 
+Therefore, the prediction distribution for (
+)
+y n
+j
++
+ based on data ( )
+Y n  is a normal distribution with 
+mean (
+)
+|
+y n
+j n
++
+ and variance 
+(
+)
+|
+d n
+j n
++
+or a standard deviation 
+(
+)
+|
+d n
+j n
++
+. The forecast 
+bands (FBs), e.g. mean ± 1.96 (~2) × standard deviation that corresponds to around 95-96% forecast 
+interval [34], are easily calculated by equations (6) and (7). Note that we define the values given by 
+
+multistep-ahead prediction procedure as ‘forecast value’ because it is calculated by using the previous 
+data in the algorithm.  
+Assessing unexpected tendencies - joint probability for detected FO 
+As the time series data is sampled as one sample at one time point, the joint probability that all of the 
+most recent years fall either above or below the predicted trend (i.e., whether there is an unexpected 
+tendency for the most recent years) should be calculated by random variables, which is generated from 
+a normal distribution. We provide the following procedure to calculate the joint probabilities in this 
+way: 
+1. Generate 10000 random number set 
+jr  by a normal distribution with mean (
+| )
+y n
+j n
++
+ and 
+variance (
+| )
+d n
+j n
++
+of the prediction values at n
+j
++
+; 
+2. The probability value 
+jp is calculated by the formula 
+        
+#{
+(
+| )}     if  (
+| ) is upper over FB
+10000
+#{
+(
+| )}     if  (
+| ) is lower under FB
+10000
+j
+j
+j
+r
+y n
+j n
+y n
+j n
+p
+r
+y n
+j n
+y n
+j n
+
+≤
++
+
++
+
+= 
+≥
++
+
++
+
+ ; 
+3. The joint probability values 
+1
+(
+,
+,
+)
+J
+P p
+p
+L
+are calculated for 
+1,
+,
+j
+J
+= L
+by 
+        
+1
+1
+(
+,
+,
+)
+J
+J
+P p
+p
+p
+p
+=
+×
+×
+L
+L
+; and     
+4. The procedure from 1 to 3 is iterated for 1000 and the averaged joint probability values are 
+calculated by 
+         
+1000
+1
+1
+1
+1
+(
+,
+,
+)
+(
+,
+,
+)
+1000
+J
+b
+J
+b
+P p
+p
+P p
+p
+=
+=
+∑
+L
+L
+. 
+ 
+A conceptual outline of this study’s analysis procedure for FO analysis is given in Fig 1. The numerical 
+procedure is implemented using MATLAB code [35], which is summarized in Supplementary folder. 
+Illustrative examples 
+The dataset for the Atlantic Multi-decadal Oscillation (AMO) is based on index monthly raw data [36], 
+while for the Norwegian Sea ecosystem, we use the yearly data assembled by the ICES integrated 
+ecosystem assessment working group for the Norwegian Sea (WGINOR, ICES (37)). Abbreviations for 
+the Norwegian Sea data used in this article is summarized in Supplementary Table1. In the examples, 
+
+we do not attempt to fully interpret any FOs revealed, but comment on the possible background for 
+some of them to illustrate the context for further work in IEA groups. 
+The Atlantic Multi-Decadal Oscillation (AMO) 
+AMO is a pronounced signal of climate variability in the North Atlantic Sea surface temperature (SST) 
+[38]. The monthly data recorded from December in 1869 to March in 2021 has been published under 
+the NCAR CLIMATE data guide [39]. We extracted monthly raw data for the period 1980-2020, from 
+which we calculated annual means, giving a time series with 31-time points. 
+To illustrate how inferences may differ for different time periods, both seven-years and three-years 
+predictions are shown for this example.  Thus, we first set the specific time point j as 2014 and 2017, 
+respectively. The stochastic difference trend model was applied to the data until j-1 time points (that is, 
+2013 and 2016). To optimize Q  for the model, we set 0.05
+0.5
+Q
+≤
+≤
+ as a search range. The 
+calculated maximum log-likelihood and optimum Q  for each dataset are summarized in Table 1a. The 
+details for the log-likelihood in the range of Q are summarized in Table 2.  
+Using the parameters of the model, the Kalman filter algorithm was run to calculate seven-years- and 
+three-years-ahead predictions. Fig 2 presents the outputs of this.  
+For the case of seven-years-ahead prediction, none of the observations for the most recent years fall 
+outside the 95% or 80% FBs, but the observation for 2015 fall outside the 70% FB. Thus, only a single 
+possible FO is identified when looking at each of the seven most recent years individually, and this is 
+due to a marked decrease in SST in 2015 that contrasts the slightly increasing trend predicted for 2014-
+2020. However, all observations for the seven most recent years fall below the predicted trend (Fig 2). 
+The joint probability for this pattern is small (Table 2), suggesting that there is a tendency in the data 
+that differs from the predicted trend and thus represents a FO. For the case of three-years-ahead 
+predictions, none of the observations from the most recent years fall outside any of the FBs, and they 
+are spread evenly around the predicted trend (Fig 2). Thus, while there are ample indications that the 
+seven most recent observations deviate from the trend predicted for the last seven years, no such pattern 
+is seen for the trend predicted for the last three years, suggesting that an assessment group may need to 
+look differently at change over these two time periods.  
+
+Norwegian Sea ecosystem 
+The Norwegian Sea is located West and Northwest of Norway, bordered by the North Sea and the 
+Atlantic Ocean to the south, the Greenland Sea to the west and the Arctic Ocean and Barents Sea to the 
+north and east. It is a deep-sea area with three species of mainly planktivorous pelagic fish making up 
+the economically most important fish stocks: mackerel (Scomber scombrus), Norwegian spring-
+spawning herring (Clupea harengus) and blue whiting (Micromesistius poutassou). Ocean currents are 
+dominated by relatively warm and saline Atlantic water masses flowing in from the south and colder 
+and fresher Arctic water masses flowing in from the northwest [40]. There is considerable negative 
+density dependence acting on biomass within the three pelagic fish stocks, presumably through 
+intraspecific competition over food [41]. While there are also indications of competition among the 
+stocks, most strongly between mackerel and herring [41], other work has suggested that interspecific 
+competition is less significant [42]. The combined biomass of the three species has increased over the 
+last decades while zooplankton biomass has declined, and it has been hypothesized that the pelagic fish 
+biomass may have exceeded the carrying capacity of the system [21]. The climate has historically varied 
+between cold and warm phases, with plankton and fish productivity tending to increase in the warmer 
+phases [43]. Here, we analyse time series on spawning stock biomass, recruitment and growth (age and 
+weight at age 6) for the three pelagic fish stocks, zooplankton biomass, and three key variables for the 
+physical environment: heat content, freshwater content and the North Atlantic Oscillation index. The 
+observations have been recorded annually, although the starting/ending years of observation vary 
+among the time series.  
+For the current work, we used time series with different start years and 2019 as the last year [37]. As 
+one of the main aims of IEAs in the Norwegian Sea has been to provide background information for 
+advisory work for operational fisheries management [44, 45], change over a short period of the most 
+recent years is typically of interest. The conditions for making the prediction were therefore set to three-
+years-ahead predictions for 2017-2019 using the data observed up to 2016. The calculated maximum 
+likelihood, and optimum Q  for each data are summarized in Table 1. The
+2
+w
+σ  was calculated using the 
+observations until 2016.  
+
+Using the parameters of the model, the Kalman filter algorithm was run to calculate three-years-ahead 
+predictions. Fig 3 presents the outputs of this. Looking at variables for the physical environment, FOs 
+for individual years were observed for relative freshwater content (RFW), where the observation for 
+2018 fall outside the 80% FB and for 2019 outside the 95% FB. In addition, observations for all of the 
+last three years fall well above the predicted trend, and the joint probability for this pattern is low (Table 
+2), indicating an unexpected tendency in the data when compared with the expected trend. While 
+freshening of the Norwegian Sea had been going on for nearly a decade before 2019 [46], these 
+unexpected increases in freshwater content point to a recent intensification of this that might require the 
+attention in IEAs of the Norwegian Sea. 
+For zooplankton biomass (ZooB), two of the most recent years fall above the 80% FB and above the 
+70% FB, with a low overall probability of the pattern (Table 2), indicating, again, an unexpected upward 
+tendency in the data. This suggests that an IEA should pay attention to a possible recovery of the 
+zooplankton biomass, which declined sharply in the early 2000s and remained at low levels in the 
+following years [18].  
+Looking at variables for pelagic fish stocks, little evidence for unexpected changes is seen for herring 
+and mackerel. For the four variables related to mackerel, no years fall outside any of the FBs and 
+observations generally lie relatively close to or on both sides of the predicted trends (Fig 3). A similar 
+pattern is seen for herring, except one estimate of recruitment falling above the 70% FB (Fig 3). As 
+pelagic fish recruitment is highly variable, a single observation falling outside the expected trend may 
+not be reason for flagging this variable for prioritization in an IEA.  
+A different picture emerges for blue whiting. For spawning stock biomass (BWB), two of the three most 
+recent years fall above the 70% FB and the third year also well above the predicted trend (Fig 3). The 
+joint probability of this pattern is low (Table 2), suggesting that there is a tendency for an increase in 
+biomass beyond the expected. At the same time, there are indications of unexpected declines in blue 
+whiting individual growth, shown for weight at age 6 (BWW), where all observations fall below the 
+70% FB (Fig 3) and the joint probability for the pattern is low (Table 2). These changes may be linked, 
+as increases in biomass tend to be associated with decreases in growth, possibly though intraspecific 
+competition over food [41]. In addition, for blue withing recruitment (BWR), two observations fall 
+
+below the 70% FB and one below the 80% FB (Fig 3) with a low joint probability for the overall pattern 
+(Table 2), indicating that the decline in recruitment for the most recent years represent an unexpected 
+tendency. Although pelagic fish recruitment remains hard to forecast (e.g. [47]), it is interesting to note 
+that considerable progress has been made in predicting variation in the geographical location of blue 
+whiting spawning habitat, which may be linked to recruitment success [48-50], thus offering a possible 
+avenue for more detailed assessments and studies following up the changes in blue whiting recruitment.  
+ 
+Discussion 
+We have introduced a time series analysis procedure for making predictions for a specific time period 
+using a structural time series model including a trend model. Based on this, we have outlined a 
+framework for investigating whether the most recent observations deviate from the predicted trend for 
+this time period and thus represent possible flagged observations (FOs). This includes assessing both 
+whether single years represent FOs or whether all of the observations from the recent years together 
+represent an unexpected tendency that is classified as a FO. The trend was estimated using a stochastic 
+trend model and observed time series data, and the specific-years-ahead predictions were systematically 
+calculated according to the iterative procedure of the Kalman filter algorithm. The statistical analysis is 
+followed by a qualitative evaluation of each FO, where it may be decided to follow some of them up by 
+more detailed analyses within an integrated ecosystem assessment (IEA). We note that applications may 
+also extend beyond IEAs to other areas of science and advisory processes where an overview of recent 
+change is required across multiple time series. 
+The time series available from marine ecosystems that are relevant for analyses described here are 
+typically short (i.e., < 50 time points) [19, 51]. This puts constraints on the types of time series analyses 
+that can be performed. For example, null hypothesis testing using a frequentist statistical approach can 
+produce misleading results, including false positive and negative results [52]. The procedure described 
+here does not include null hypothesis statistical testing, and the type of structural time series model used 
+by us is not based on a frequentist framework but corresponds to a Bayesian approach [53], which may 
+properly assess trends in short time series that cannot be analysed using a frequentist approach [52]. An 
+
+alternative method to the one used here could have been the Box Jenkins model, which transforms a 
+non-stationary mean time series to a stationary process [54]. However, effective fitting using this 
+method, again, requires longer time series than what is normally available in marine ecosystems [19, 
+51]. Thus, for short time series, the Bayesian framework used here appears to be more robust than 
+alternative approaches. 
+To study and assess recent change, IEA groups often rely on examinations of anomaly plots. In such 
+plots, recent change appears as deviations from a long-term mean, often estimated for the whole length 
+of the time series (see e.g. Bulgin, Merchant (55) for an application to global sea surface temperatures, 
+SST). By focusing on deviations from the expected trend for the most recent years (where the expected 
+trend is estimated by using information from the whole time series), FO analysis can provide a different 
+perspective of recent change. For example, using a seven-years prediction, the FO analysis indicates 
+that there is a tendency in North Atlantic Sea SST towards a more negative trend than what should be 
+expected for the last 7 years of the time series. We argue that the same interpretation is less evident 
+from an anomaly plot of the same time series (see Supplementary Fig 1). Thus, while positive and 
+negative values indicate how observations deviate from a constant mean value in an anomaly plot, the 
+trend changes through time, making it harder to assess how the most recent observations deviate from 
+the trend that should be expected for these recent years. Recognizing that anomaly plots are important 
+for a large range of purposes within IEAs, we emphasize that FO analysis can provide useful additional 
+information for the practical work in IEA groups, in particular in the light of the challenge they are 
+often faced with of understanding and assessing the most recent development of an ecosystem [14]. 
+Since the cumulative output of FO analysis also aim at giving a sweeping overview of the recent 
+dynamics of all the measured elements in an ecosystem by highlighting the variables that exhibit 
+unexpected change while at the same time showing trends and data for those that do not, the approach 
+should be useful for facilitating the necessary dialogue between scientists and stakeholders about recent 
+ecosystem change within the process of an IEA. Such overviews can also contribute to the scientific 
+output used to educate and inform the public and the political system during parts of policymaking 
+processes related to for example ecosystem-based management [56]. 
+ 
+
+Acknowledgements 
+We would like to thank Benjamin Planque, who motivated us to consider this approach to analysing the 
+time series data compiled by the ICES integrated ecosystem assessment working groups and Mette 
+Mauritzen and Daniel Howell for comments on an earlier draft of the paper. This study was carried out 
+as part of the project “Sustainable multi-species harvest from the Norwegian Sea and adjacent 
+ecosystems”, funded by The Research Council of Norway (pr. nr. 299554). 
+ 
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+PMID: WOS:000397136400039. 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+
+Table 1. Calculated log-likelihood (LL) and the optimum Q  by applying stochastic trend model for 
+2
+d =
+for the AMO and Norwegian Sea ecosystem datasets. 
+ 
+Dataset 
+Variable 
+Q 
+Maximum log-
+likelihood 
+AMO 
+AMOS 
+0.50 
+-51.2 
+Norwegian Sea 
+ecosystem 
+(WGINOR) 
+RHC 
+0.05 
+-82.8 
+RFW 
+0.08 
+-82.6 
+NAO 
+0.05 
+-161.3 
+ZooB 
+0.09 
+-29.1 
+MacB 
+0.12 
+-43.3 
+MacR 
+0.06 
+-42.1 
+MacW 
+0.07 
+-44.1 
+MacL 
+0.07 
+-71.8 
+HerB 
+0.06 
+-125.7 
+HerR 
+0.05 
+-42.6 
+HerW 
+0.11 
+-87.1 
+HerL 
+0.08 
+-93.7 
+BWB 
+0.13 
+-42.4 
+BWR 
+0.16 
+-48.7 
+BWW 
+0.09 
+-43.8 
+BWL 
+0.08 
+-57.3 
+ 
+ 
+ 
+ 
+Table 2. Averaged p-values and joint probability for the prediction and observation for 
+AMOS, RFW, ZooB, BWB, BWR, and BWW. 
+ 
+Year 
+AMOS 
+RFW 
+ZooB 
+BWB 
+BWR 
+BWW 
+2014 
+0.19 
+ 
+2015 
+0.14 
+2016 
+0.29 
+2017 
+0.42 
+0.22 
+0.12 
+0.13 
+0.1003 
+0.12 
+2018 
+0.22 
+0.061 
+0.28 
+0.16 
+0.1237 
+0.11 
+2019 
+0.28 
+0.023 
+0.13 
+0.29 
+0.1415 
+0.13 
+2020 
+0.42 
+ 
+Joint 
+probability 
+8.24e-05 
+3.06e-04 
+0.0045 
+0.0063 
+0.0018 
+0.0016 
+ 
+ 
+ 
+
+ 
+ 
+Fig1. Outline of proposed Flagged observation (FO) analysis 
+
+Time series data
+2.5
+Estimationof thetrend
+1.5
+Ecosystem-based
+in the period 1950 - 2016
+fisheries management
+and
+0.
+prediction of the data
+contribution
+in the period 2017-2019
+1960
+1970
+1980
+1990
+2000
+2010
+12020
+Yea
+Dataintheperiod1950-2016
+RealdataoutsideofFBs
+deviatedfromrecent3-year
+Estimated trend =(n)
+trend - Flagged observation
+17
+RealdatawithinFBsfollowed
+recent 3-year trend
+Forecast bands (FBs)
+y(n+jln)+2×/d(n+j|n)
+1619
+Prediction of the data
+y(n+ jln), j=1, 2, 3 
+ 
+         
+ 
+    
+Fig 2. The estimated three-years (upper) and seven-years (lower) prediction values of sea 
+surface temperature and the most recent observations for the dataset on the Atlantic 
+Multi-decadal Oscillation. The solid grey lines indicate the observations used for making 
+the forecast values and the black points indicate the observations that were plotted for 
+comparison with the prediction values (dotted blue line). The dotted grey line presents 
+the prediction value 
+and the solid blue lines present the smoothed trend 
+estimates obtained by a fixed-interval smoother algorithm.  The band coloured by light-
+blue presents the 95% FB, 80% and approximately 70% FBs, which upper and lower limits 
+were calculated by mean 
+± 1.96 (1.28, 1) × standard deviation 
+, 
+where 
+or 
+. The observations in the years applying the prediction are 
+shown with black points.   
+ 
+ 
+
+0.6
+0.4
+0.2
+0.2
+-0.4
+-0.6
+-0.8
+-1
+1980
+17
+20
+lyearelsius]
+.0.5
+-0.5
+1980
+06
+0913
+1619
+[year]Climate: 
+ 
+Plankton: 
+ 
+ 
+Fig 3 Continued. 
+   
+          
+ 
+    
+ 
+   
+ 
+
+RHC
+225
+-wr
+[108
+20
+15
+10
+5
+0
+-5
+-10
+-15
+1951
+1619
+[year]RFW
+E
+1.5
+1
+0.5
+0.5
+-1.5
+2
+1951
+1619
+[year]NAO
+[djfm]
+5
+-2
+3
+1907
+1619
+[year]ZooB
+235
+[gm-2
+30
+25
+20
+15
+10
+1995
+16
+19
+[year]Pelagic fish: 
+Fig 3 Continued. 
+    
+      
+ 
+         
+ 
+   
+      
+ 
+  
+           
+ 
+ 
+
+MacB
+6
+5
+1
+3
+2
+1
+0
+1980
+1619
+[year]X106
+MacR
+4.597
+o!l
+4.596
+4.595
+4.594
+4.593
+4.592
+4.591
+4.59
+4.589
+4.588
+1980
+1619
+[vear]MacW
+0.1
+0.05
+0
+-0.05
+0.1
+-0.15
+1980
+16
+19
+[year]MacL
+48
+46
+44
+42
+40
+38
+1963
+16 19
+[year]HerB
+tonnes
+45
+40
+[million t
+35
+30
+25
+20
+15
+10
+5
+1907
+1619
+[year]X108
+HerR
+2.7868
+O
+2.7866
+2.7864
+2.7862
+2.786
+2.7858
+2.7856
+2.7854
+1988
+16
+19
+[year]Herw
+0.2
+0.15
+0.1
+0.05
+0
+-0.05
+0.1
+-0.15
+0.2
+1950
+1619
+[year]HerL
+44
+42
+40
+38
+36
+34
+1944
+1619
+[year]Pelagic fish: 
+Fig 3. The estimated three-years prediction values and the three most recent observations for 
+data on variables related to climate, plankton and pelagic fish in the Norwegian Sea 
+ecosystem. The solid grey lines indicate the observations used for making the forecast values 
+and the black points indicate the observations that were plotted for comparison with the 
+prediction values (dotted blue line). The dotted grey line presents the prediction value 
+and the solid blue lines present the smoothed trend estimates obtained by a 
+fixed-interval smoother algorithm.  The band coloured by light-blue presents the 95% FB, 80% 
+and approximately 70% FBs, which upper and lower limits were calculated by mean 
+± 1.96 (1.28, 1) × standard deviation 
+, where 
+. The 
+observations in the years applying the prediction are shown with black points.   
+ 
+ 
+ 
+ 
+ 
+    
+     
+ 
+  
+        
+ 
+ 
+
+BWB
+[milliont
+10
+8
+6
+4
+2
+0
+2
+1981
+1619
+[year]X108
+BWR
+3.1656
+3.1652
+3.165
+3.1648
+3.1646
+3.1644
+3.1642
+1981
+1619
+lyearBWW
+0.06
+0.04
+0.02
+0
+0.02
+-0.04
+-0.06
+-0.08
+1981
+16
+19
+[year]BWL
+48
+46
+44
+42
+40
+38
+1972
+1619
+[year]Supplementary Fig 1 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+Supplementary Fig 1. Bar plots for anomalies of AMOS’s yearly data from 1980 to 2020. The y-
+axis indicates the value subtracting mean value of yearly data from 1980 to 2020. The x-axis 
+indicates year. The negative/positive values correspond lower/higher temperature to the mean 
+value. 
+
+0.4
+0.3
+0.2
+0.1
+0
+-0.1
+0.2
+-0.3
+-0.4
+1980
+1985
+1990
+1995
+20002
+2005
+2010
+2015
+2020Supplementary Table. Abbreviations used in figures and tables 
+Type 
+Abbreviation 
+in figures 
+and tables 
+Explanation of relevant data 
+ 
+Climate 
+RHC 
+Relative heat content in 108 Jm-2 
+RFW 
+Relative freshwater content in m 
+NAO 
+North Atlantic Oscillation expressed as djfm 
+Zooplankton 
+ZooB 
+Total zooplankton biomass the Norwegian Sea in in May, g m-2  
+ 
+ 
+ 
+ 
+ 
+ 
+Pelagic fish 
+MacB 
+Spawning stock biomass of Mackerel in million tonnes 
+MacR 
+Recruitment of Mackerel per year class at age 0 in millions 
+MacW 
+Weight of Mackerel at age 6 in the stock (in kg) 
+MacL 
+Length of Mackerel at age 6 in cm 
+HerB 
+Spawning stock biomass of Herring in million tonnes 
+HerR 
+Recruitment of Herring per year class at age 2 in millions 
+HerW 
+Weight of Herring at age 6 in the stock (in kg) 
+HerL 
+Length of Herring at age 6 in cm 
+BWB 
+Spawning stock biomass of Blue whiting in million tonnes 
+BWR 
+Recruitment of Blue whiting per year class at age 1 in millions 
+BWW 
+Weight of Blue whiting age 6 in the catch (in kg) 
+BWL 
+Length of Blue whiting at age 6 in cm 
+ 
+ 
+ 
+ 
+
diff --git a/8dE3T4oBgHgl3EQfRwni/content/tmp_files/load_file.txt b/8dE3T4oBgHgl3EQfRwni/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..47df81f248b57175480b67679ad3057012e02aab
--- /dev/null
+++ b/8dE3T4oBgHgl3EQfRwni/content/tmp_files/load_file.txt
@@ -0,0 +1,869 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf,len=868
+page_content='Flagged observation analyses as a tool for scoping and communication in  Integrated Ecosystem Assessments  Solvang, Hiroko Kato  Institute of Marine Research, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Box 1870 Nordnes, N-5817 Bergen, Norway  hirokos@hi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='no  Arneberg, Per  Institute of Marine Research, Fram Centre, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Box 6606, 9296 Langnes, Norway  perab@hi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='no  Abstract  Working groups for integrated ecosystem assessments are often challenged with understanding and  assessing recent change in ecosystems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' As a basis for this, the groups typically have at their disposal  many time series and will often need to prioritize which ones to follow up for closer analyses and  assessment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Here we provide a procedure termed Flagged observation analyses that can be applied to  all the available time series to help identifying time series that should be prioritized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The statistical  procedure first applies a structural time series model including a stochastic trend model to the data to  estimate the long-term trend.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The model adopts a state space representation, and the trend component  is estimated by a Kalman filter algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The algorithm obtains one- or more-years-ahead prediction  values using all past information from the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Thus, depending on the number of years the investigator  wants to consider as “the most recent”, the expected trend for these years is estimated through the  statistical procedure by using only information from the years prior to them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Forecast bands are  estimated around the predicted trends for the recent years, and in the final step, an assessment is made  on the extent to which observations from the most recent years fall outside these forecast bands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Those  that do, may be identified as flagged observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' A procedure is also presented for assessing whether  the combined information from all of the most recent observations form a pattern that deviates from the  predicted trend and thus represents an unexpected tendency that may be flagged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In addition to form the  basis for identifying time series that should be prioritized in an integrated ecosystem assessment,  flagged observations can provide the basis for communicating with managers and stakeholders about  recent ecosystem change.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Applications of the framework are illustrated with two worked examples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Keywords: Trend estimation, Kalman filter, Prediction, Forecast band, Stakeholder, Climate change  Introduction  Against a background of increasing impact from climate change and other anthropogenic drivers,  causing elevated rates of change in marine ecosystems [1-6] leading to patterns of variability beyond  the range of the Holocene [7-12], ecosystem-based management (EBM) is increasingly identified as a  needed framework for management of marine socio-ecological systems [13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Integrated ecosystem  assessments (IEA) have been developed to provide the scientific basis for EBM [14], and numerous  groups of scientists working with IEA have been established, such as the regional IEA groups within  the International Council for the Exploration of the Sea (ICES, Walther and Möllmann (15)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Among the core activities of IEA groups are analyses of time series to summarize changes that have  occurred in recent decades in ecosystems, highlight possible connections between physical, biological,  and human ecosystem components [14, 16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Emphasis is put on keeping an open communication  management and stakeholders [13, 17, 18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' As the groups typically have at their disposal a large number  of time series [16, 19], it will often be necessary to prioritize a subset of them for more extensive  analyses and communication purposes [20, 21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Prioritization should preferably be done using a  standardized framework applied to all time series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Here we present an approach which is based analyses  of patterns of recent change, where the aim is to identify time series in which the most recent values  deviate significantly from an expected trend, possibly indicating unexpected change.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This should be of  high relevance for IEA groups, as they are often challenged with understanding and interpreting recent  change [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Our approach is based on first estimating trends of time series before assessing whether the most recent  observations deviate significantly from these trends.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Since temporal changes in ecosystems can take the  form of long-term movements as well as short- or mid-term cyclic periods and noise components,  different definitions of trends have been used in marine IEAs [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In the field of statistical time series  analysis, the long-term movements are commonly classified as ‘trends’, while short- or mid-term cyclic  periods are not, due to the different assumptions about the statistical properties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' When investigating a  trend in time series data, it can therefore be useful to separately identify non-stationary trends and  stationary cyclic components.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This decomposition is performed by a framework called ‘structural time  series modelling’, which is using a state space representation where the state of each component is  estimated by the Kalman filter algorithm [22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The concept is basically different from applying an  Autoregressive integrated moving average model to adjust with the aim of studying stationary processes  from nonstationary time series data [23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The Kalman filter algorithm can make one- or multistep-ahead predictions in the numerical procedure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The numerical procedure introduced in this paper uses prediction values and forecast uncertainty bands  to assess the status of a recent observation, which determines whether the most recent observation  follows the prediction or deviates from it [24], thus giving an indication whether change that is  unexpected from the predicted trend, is occurring in the time series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' We call the significant deviated  observations a “Flagged Observation (FO)” and the approach “Flagged Observation analysis”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The  interpretation of a FO is not equivalent to the types of early warning signals that have been proposed  with the aim of predicting critical transitions in marine populations or ecosystems [25, 26], nonlinear  ecological change [27] or early warning signs based on theoretical framework in social-ecological  networks [28], but is, as described above, a practical tool for IAE groups for prioritizing time series for  in depth analyses, communication and other purposes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  In this article, we first introduce the numerical procedure and then demonstrate two examples using  time series data for, respectively, the Atlantic Multi-decadal Oscillation (AMO) and the Norwegian Sea  ecosystem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Statistical method  The statistical method includes first a procedure for trend estimation and second a procedure for flagged  observations analyses (FO analyses) based on multistep ahead prediction values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The output from these  analyses can be used to identify observations (for example years) that deviate significantly from the  expected trend.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In addition, it can also be interesting to explore whether observations from the predicted  years together form a pattern where all are consecutively either above or below the predicted trend in a  way that is not expected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This is equivalent to asking whether there is an unexpected tendency for the  most recent years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The probability for observing this is smaller than the probability of detecting an FO  for a single observation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The details are given as below:  Trend estimation procedure  The observation model of a time series is given by  ( )  ( )  ( ),  1,  ,  y n  t n  u n  n  N  =  +  =  ⋅⋅⋅  ,  (1)  where ( )  t n is the trend component and ( )  u n is the residual component at time step n, assuming Gaussian  white noise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In this article, we introduce a stochastic trend model given by a dth-order difference  equation model and a method for estimating the trend [29, 30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The stochastic differential trend model is defined by the dth-order difference equation, which was posed  as a smoothing problem by [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This model allows for more flexible trends than does the polynomial  regression model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The stochastic trend model for k variables is expressed in the following way:  ( )  ( ),  1,  , ,  i  d  i  t  t n  v n  i  k  ∇  =  =  ⋅⋅⋅  (2)  where ∇ is a difference operator  ( )  ( )  (  1)  t n  t n  t n  ∇  =  −  −  and  ( )  itv n  is assumed to be a white noise  sequence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' If  1  d =  , ( )  (  1)  t n  t n  ≈  −  and the trend is known as a random walk model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' If  2  d =  ,  ( )  2 (  1)  (  2)  0  t n  t n  t n  −  −  +  −  ≈  [29].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Provided that the variance of  ( )  itv n  is sufficiently small, ( )  it n  yields a smooth trend.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' We choose the second order difference stochastic model to estimate trend in this  study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The model can be represented in linear state space form [22, 29, 30], as  ( )  (  1)  ( ),  ( )  ( )  ( ),  z n  Fz n  Gv n  y n  Hz n  w n  =  −  +  =  +  (3)  where ( )  z n is the state vector corresponding to ( )  t n , ( )  v n  is the system noise vector with mean 0 and  unknown variance  2  v  σ , F ,G , and H indicate integers or matrices, and  ( )  w n  is observation error  with mean 0 and unknown variance  2  w  σ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The state ( )  z n corresponds to the trend component, which we  cannot directly observe from the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The component is modelled by the dth-order differential equation  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Corresponding to the above dth-order difference equation, when  1  d =  in equation (2),  ( )  ( )  t n  z n  \uf8ee  \uf8f9  \uf8f0  \uf8fb  =  ,  1  F  G  H  =  =  =  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  When  2  d =  , the state vector and matrices are as follows:  ( )  ( )  (  1)  t n  z n  t n  \uf8ee  \uf8f9  = \uf8ef  \uf8fa  −  \uf8f0  \uf8fb ,  2  1  1  0  F  −  \uf8eb  \uf8f6  = \uf8ec  \uf8f7  \uf8ed  \uf8f8,  1  0  G  \uf8ee \uf8f9  = \uf8ef \uf8fa  \uf8f0 \uf8fb  , and  1  0  H  \uf8ee \uf8f9  = \uf8ef \uf8fa  \uf8f0 \uf8fb  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The observation error corresponds to ( )  u n in equation (1) in this case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The trend component is estimated  with a Kalman filter,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' which is a powerful numerical algorithm that recursively operates the state  estimation,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=" prediction and filtering:  prediction:  ( |  1)  (  1|  1)  ( |  1)  (  1|  1)  '  z n n  Fz n  n  V n n  FV n  n  GQG  −  =  −  −  −  =  −  −  +  (4)  filtering:  1  ( )  ( |  1)  '(  ( |  1)  '  )  ( | )  ( |  1)  ( ( )  ( |  1))  ( | )  (  ) ( |  1)  K n  V n n  H  H V n n  H  R  z n n  z n n  K y n  H z n n  V n n  I  K H V n n  −  =  −  −  +  =  −  +  −  −  =  −  −  (5)  Here," metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' ( |  1)  z n n −  and  ( |  1)  V n n −  correspond to the conditional mean and conditional variance of the  state,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' R  is set as the observation error,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' and K  is called the Kalman gain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Setting the initial state  (  )  1| 0  z  and variance  (  )  1| 0  V  as zero and the pre-determined system noise, the Kalman gain is  calculated by the initial variance and observation noise, and the filtering value (  )  1|1  z  is obtained by  using observation  ( )  1  y  and the calculated gain from the filtering procedure (5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Then the next  prediction values (  )  2 |1  z  and  (  )  2 |1  V  are calcualted using (  )  1|1  z  and  (  )  1|1  V  in the prediction  procedure (4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The iterative calculation procedure for the state is continued until n  N  =  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Recursive  methods based on state space representations are known to be very efficient for calculating the  likelihood functions of discrete-time Gaussian proceeses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The state space model and the Kalman filter  provide an efficient method for the computation of the likelihood of the time series models [29].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In this  case, the trend model includes the parameter vector  2  2  ( ,  ,  )  v  w  d  θ  σ  σ  =  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=" The log-likelihood function ( )  l θ  of the model is given by  1  1  1  2  ( )  log  ( ( ) |  (  1), ),  1  1  log  exp  ( )' ( )  ( )  ,  2  (2 ) det ( )  N  n  N  n  l  f y n  Y n  y n  n  y n  n  θ  θ  π  =  −  =  =  −  \uf8f1  \uf8fc  \uf8f4  \uf8f4  \uf8eb  \uf8f6  =  −  ∆  Σ  ∆  \uf8f2  \uf8fd  \uf8ec  \uf8f7  \uf8ed  \uf8f8  Σ  \uf8f4  \uf8f4  \uf8f3  \uf8fe  ∑  ∑  where  (  1)  ( (1), (2),  , (  1))  Y n  y  y  y n  −  =  ⋅⋅⋅  −  ,  ( )  ( )  ( |  1)  y n  y n  Hz n n  ∆  =  −  −  ,  and  2  ( )  ( )  ( |  1)  '( )  w  n  H n V n n  H n  σ  Σ  =  −  +  ." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The flexibility of the estimated trend depends on  2  v  σ , which can be  determined by maximum likelihood within an arbitry variance range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The variance  2  w  σ  can be directly  set to the variance of the observation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' If it is necessary to compare differernt order differential stochastic  model, the optimum differential order d is identified by the AIC [32] , which was formulated by the  maximum log-likelihood and number of parameters for d and the variances of system noise and  observation noise, given by AIC( )  2 ( )  2  number of parameters  c  l θ  = −  +  ×  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  After identifying the optimum trend model,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=" the smoothed trend is estimated by a fixed-interval  smoother algorithm [33]:  1  ( )  ( | )  ' (  1| )  ( |  )  ( | )  ( )( (  1|  )  (  1| ))  ( |  )  ( | )  ( )( (  1|  )  (  1| )) ( )'  A n  V n n F V n  n  z n N  z n n  A n  z n  N  z n  n  V n N  V n n  A n V n  N  V n  n A n  −  =  +  =  +  +  −  +  =  +  +  −  +  In this study," metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' we set the differential order as  2  d =  to obtain smooth trend for all time series data as  introduced in Kitagawa and Gersch (33) and take a procedure finding an optimum Q controlling  variability for the trend estimation within a range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  FO analysis by multistep-ahead prediction values  Using the Kalman filter algorithm directly, it can give only one-ahead prediction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' However, it can be  expanded to multistep-ahead (j-ahead) prediction (  1  j >  ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Let us consider a relevant situation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' With the  Kalman filter, one-ahead prediction for (  )  1  z n +  is obtained by (  )  1|  z n  n  +  and variance (  )  1|  V n  n  +  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  If the data  (  )  1  y n +  are not observed, the calculation is formally conducted by assuming  (  )  ( )  1  Y n  Y n  +  =  ,  where  (  )  ( )  (1), (2),  , ( )  Y n  y  y  y n  =  ⋅⋅⋅  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Accordingly,  it  is  clear  that  (  )  (  )  1|  1  1|  z n  n  z n  n  +  +  =  +  and  (  )  (  )  1|  1  1|  V n  n  V n  n  +  +  =  +  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Then, two-ahead prediction  (  )  2 |  z n  n  +  and variance  (  )  2 |  V n  n  +  are obtained by (  )  1|  z n  n  +  and (  )  1|  V n  n  +  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In general, we  assume ( )  (  1)  (  )  Y n  Y n  Y n  j  =  +  = ⋅⋅⋅ =  +  to obtain the j-ahead prediction, and the prediction step is  iteratively conducted j times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=" The algorithm used to predict states (  )  (  )  (  )  1 ,  2 ,  ,  z n  z n  z n  j  +  +  ⋅⋅⋅  +  ,  based on the data ( )  Y n  observed until time point n , is expressed as follows:  (  )  (  )  (  )  (  )  |  1|  ,  |  1|  '  ',  1,  , ." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  z n  i n  Fz n  i  n  V n  i n  FV n  i  n F  GQG  i  j  +  =  + −  +  =  + −  +  =  ⋅⋅⋅  Now, let the mean and variance for the prediction (  )  y n  j  +  of the data denote  (  )  ( )  (  )  E  |  y n  j  Y n  +  and  (  )  ( )  (  )  Cov  |  y n  j  Y n  +  , where  ( )  E ⋅  and  ( )  Cov ⋅  are notations for expectation and variance-  covariance matrix (but in this study only variance because the data are univariate).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Using the  observation equation (3), the mean of (  )  y n  j  +  is expressed by  (  )  (  )  (  )  ( )  (  )  (  )  |  =E  |  |  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content="  y n  j n  Hz n  j  w n  j  Y n  Hz n  j n  +  +  +  +  =  +  (6)  The variance of (  )  y n  j  +  is given by  (  )  (  )  (  )  ( )  (  )  (  )  ( )  (  )  (  )  (  )  ( )  (  )  (  )  (  )  ( )  (  )  (  )  ( )  (  )  (  )  (  )  |  =Cov  |  ,  Cov  |  '  Cov  ,  |  Cov  ,  |  ' Cov  |  ,  |  '  ." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  d n  j n  Hz n  j  w n  j  Y n  H  z n  j  Y n  H  H  z n  j  w n  j  Y n  w n  j  z n  j  Y n  H  w n  j  Y n  H V n  j n H  R n  j  +  +  +  +  =  +  +  +  +  +  +  +  +  +  =  +  +  +  (7)  Therefore, the prediction distribution for (  )  y n  j  +  based on data ( )  Y n  is a normal distribution with  mean (  )  |  y n  j n  +  and variance  (  )  |  d n  j n  +  or a standard deviation  (  )  |  d n  j n  +  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The forecast  bands (FBs), e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' mean ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='96 (~2) × standard deviation that corresponds to around 95-96% forecast  interval [34], are easily calculated by equations (6) and (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Note that we define the values given by  multistep-ahead prediction procedure as ‘forecast value’ because it is calculated by using the previous  data in the algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Assessing unexpected tendencies - joint probability for detected FO  As the time series data is sampled as one sample at one time point, the joint probability that all of the  most recent years fall either above or below the predicted trend (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=', whether there is an unexpected  tendency for the most recent years) should be calculated by random variables, which is generated from  a normal distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' We provide the following procedure to calculate the joint probabilities in this  way:  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Generate 10000 random number set  jr  by a normal distribution with mean (  | )  y n  j n  +  and  variance (  | )  d n  j n  +  of the prediction values at n  j  +  ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The probability value  jp is calculated by the formula  #{  (  | )}     if  (  | ) is upper over FB  10000  #{  (  | )}     if  (  | ) is lower under FB  10000  j  j  j  r  y n  j n  y n  j n  p  r  y n  j n  y n  j n  \uf8f1  ≤  +  \uf8f4  +  \uf8f4\uf8f4\uf8f4  = \uf8f2\uf8f4  ≥  +  \uf8f4  +  \uf8f4\uf8f4\uf8f3  ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The joint probability values  1  (  ,  ,  )  J  P p  p  L  are calculated for  1,  ,  j  J  = L  by  1  1  (  ,  ,  )  J  J  P p  p  p  p  =  ×  ×  L  L  ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' and  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The procedure from 1 to 3 is iterated for 1000 and the averaged joint probability values are  calculated by  1000  1  1  1  1  (  ,  ,  )  (  ,  ,  )  1000  J  b  J  b  P p  p  P p  p  =  =  ∑  L  L  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  A conceptual outline of this study’s analysis procedure for FO analysis is given in Fig 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The numerical  procedure is implemented using MATLAB code [35], which is summarized in Supplementary folder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Illustrative examples  The dataset for the Atlantic Multi-decadal Oscillation (AMO) is based on index monthly raw data [36],  while for the Norwegian Sea ecosystem, we use the yearly data assembled by the ICES integrated  ecosystem assessment working group for the Norwegian Sea (WGINOR, ICES (37)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Abbreviations for  the Norwegian Sea data used in this article is summarized in Supplementary Table1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In the examples,  we do not attempt to fully interpret any FOs revealed, but comment on the possible background for  some of them to illustrate the context for further work in IEA groups.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The Atlantic Multi-Decadal Oscillation (AMO)  AMO is a pronounced signal of climate variability in the North Atlantic Sea surface temperature (SST)  [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The monthly data recorded from December in 1869 to March in 2021 has been published under  the NCAR CLIMATE data guide [39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' We extracted monthly raw data for the period 1980-2020, from  which we calculated annual means, giving a time series with 31-time points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  To illustrate how inferences may differ for different time periods, both seven-years and three-years  predictions are shown for this example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Thus, we first set the specific time point j as 2014 and 2017,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The stochastic difference trend model was applied to the data until j-1 time points (that is,  2013 and 2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' To optimize Q  for the model, we set 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='5  Q  ≤  ≤  as a search range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The  calculated maximum log-likelihood and optimum Q  for each dataset are summarized in Table 1a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The  details for the log-likelihood in the range of Q are summarized in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Using the parameters of the model, the Kalman filter algorithm was run to calculate seven-years- and  three-years-ahead predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Fig 2 presents the outputs of this.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  For the case of seven-years-ahead prediction, none of the observations for the most recent years fall  outside the 95% or 80% FBs, but the observation for 2015 fall outside the 70% FB.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Thus, only a single  possible FO is identified when looking at each of the seven most recent years individually, and this is  due to a marked decrease in SST in 2015 that contrasts the slightly increasing trend predicted for 2014-  2020.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' However, all observations for the seven most recent years fall below the predicted trend (Fig 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The joint probability for this pattern is small (Table 2), suggesting that there is a tendency in the data  that differs from the predicted trend and thus represents a FO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' For the case of three-years-ahead  predictions, none of the observations from the most recent years fall outside any of the FBs, and they  are spread evenly around the predicted trend (Fig 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Thus, while there are ample indications that the  seven most recent observations deviate from the trend predicted for the last seven years, no such pattern  is seen for the trend predicted for the last three years, suggesting that an assessment group may need to  look differently at change over these two time periods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Norwegian Sea ecosystem  The Norwegian Sea is located West and Northwest of Norway, bordered by the North Sea and the  Atlantic Ocean to the south, the Greenland Sea to the west and the Arctic Ocean and Barents Sea to the  north and east.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' It is a deep-sea area with three species of mainly planktivorous pelagic fish making up  the economically most important fish stocks: mackerel (Scomber scombrus), Norwegian spring-  spawning herring (Clupea harengus) and blue whiting (Micromesistius poutassou).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Ocean currents are  dominated by relatively warm and saline Atlantic water masses flowing in from the south and colder  and fresher Arctic water masses flowing in from the northwest [40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' There is considerable negative  density dependence acting on biomass within the three pelagic fish stocks, presumably through  intraspecific competition over food [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' While there are also indications of competition among the  stocks, most strongly between mackerel and herring [41], other work has suggested that interspecific  competition is less significant [42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The combined biomass of the three species has increased over the  last decades while zooplankton biomass has declined, and it has been hypothesized that the pelagic fish  biomass may have exceeded the carrying capacity of the system [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The climate has historically varied  between cold and warm phases, with plankton and fish productivity tending to increase in the warmer  phases [43].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Here, we analyse time series on spawning stock biomass, recruitment and growth (age and  weight at age 6) for the three pelagic fish stocks, zooplankton biomass, and three key variables for the  physical environment: heat content, freshwater content and the North Atlantic Oscillation index.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The  observations have been recorded annually, although the starting/ending years of observation vary  among the time series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  For the current work, we used time series with different start years and 2019 as the last year [37].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' As  one of the main aims of IEAs in the Norwegian Sea has been to provide background information for  advisory work for operational fisheries management [44, 45], change over a short period of the most  recent years is typically of interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The conditions for making the prediction were therefore set to three-  years-ahead predictions for 2017-2019 using the data observed up to 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The calculated maximum  likelihood, and optimum Q  for each data are summarized in Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The  2  w  σ  was calculated using the  observations until 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Using the parameters of the model, the Kalman filter algorithm was run to calculate three-years-ahead  predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Fig 3 presents the outputs of this.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Looking at variables for the physical environment, FOs  for individual years were observed for relative freshwater content (RFW), where the observation for  2018 fall outside the 80% FB and for 2019 outside the 95% FB.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In addition, observations for all of the  last three years fall well above the predicted trend, and the joint probability for this pattern is low (Table  2), indicating an unexpected tendency in the data when compared with the expected trend.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' While  freshening of the Norwegian Sea had been going on for nearly a decade before 2019 [46], these  unexpected increases in freshwater content point to a recent intensification of this that might require the  attention in IEAs of the Norwegian Sea.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  For zooplankton biomass (ZooB), two of the most recent years fall above the 80% FB and above the  70% FB, with a low overall probability of the pattern (Table 2), indicating, again, an unexpected upward  tendency in the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This suggests that an IEA should pay attention to a possible recovery of the  zooplankton biomass, which declined sharply in the early 2000s and remained at low levels in the  following years [18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Looking at variables for pelagic fish stocks, little evidence for unexpected changes is seen for herring  and mackerel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' For the four variables related to mackerel, no years fall outside any of the FBs and  observations generally lie relatively close to or on both sides of the predicted trends (Fig 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' A similar  pattern is seen for herring, except one estimate of recruitment falling above the 70% FB (Fig 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' As  pelagic fish recruitment is highly variable, a single observation falling outside the expected trend may  not be reason for flagging this variable for prioritization in an IEA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  A different picture emerges for blue whiting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' For spawning stock biomass (BWB), two of the three most  recent years fall above the 70% FB and the third year also well above the predicted trend (Fig 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The  joint probability of this pattern is low (Table 2), suggesting that there is a tendency for an increase in  biomass beyond the expected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' At the same time, there are indications of unexpected declines in blue  whiting individual growth, shown for weight at age 6 (BWW), where all observations fall below the  70% FB (Fig 3) and the joint probability for the pattern is low (Table 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' These changes may be linked,  as increases in biomass tend to be associated with decreases in growth, possibly though intraspecific  competition over food [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In addition, for blue withing recruitment (BWR), two observations fall  below the 70% FB and one below the 80% FB (Fig 3) with a low joint probability for the overall pattern  (Table 2), indicating that the decline in recruitment for the most recent years represent an unexpected  tendency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Although pelagic fish recruitment remains hard to forecast (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' [47]), it is interesting to note  that considerable progress has been made in predicting variation in the geographical location of blue  whiting spawning habitat, which may be linked to recruitment success [48-50], thus offering a possible  avenue for more detailed assessments and studies following up the changes in blue whiting recruitment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Discussion  We have introduced a time series analysis procedure for making predictions for a specific time period  using a structural time series model including a trend model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Based on this, we have outlined a  framework for investigating whether the most recent observations deviate from the predicted trend for  this time period and thus represent possible flagged observations (FOs).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This includes assessing both  whether single years represent FOs or whether all of the observations from the recent years together  represent an unexpected tendency that is classified as a FO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The trend was estimated using a stochastic  trend model and observed time series data, and the specific-years-ahead predictions were systematically  calculated according to the iterative procedure of the Kalman filter algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The statistical analysis is  followed by a qualitative evaluation of each FO, where it may be decided to follow some of them up by  more detailed analyses within an integrated ecosystem assessment (IEA).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' We note that applications may  also extend beyond IEAs to other areas of science and advisory processes where an overview of recent  change is required across multiple time series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  The time series available from marine ecosystems that are relevant for analyses described here are  typically short (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=', < 50 time points) [19, 51].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This puts constraints on the types of time series analyses  that can be performed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' For example, null hypothesis testing using a frequentist statistical approach can  produce misleading results, including false positive and negative results [52].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The procedure described  here does not include null hypothesis statistical testing, and the type of structural time series model used  by us is not based on a frequentist framework but corresponds to a Bayesian approach [53], which may  properly assess trends in short time series that cannot be analysed using a frequentist approach [52].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' An  alternative method to the one used here could have been the Box Jenkins model, which transforms a  non-stationary mean time series to a stationary process [54].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' However, effective fitting using this  method, again, requires longer time series than what is normally available in marine ecosystems [19,  51].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Thus, for short time series, the Bayesian framework used here appears to be more robust than  alternative approaches.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  To study and assess recent change, IEA groups often rely on examinations of anomaly plots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' In such  plots, recent change appears as deviations from a long-term mean, often estimated for the whole length  of the time series (see e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Bulgin, Merchant (55) for an application to global sea surface temperatures,  SST).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' By focusing on deviations from the expected trend for the most recent years (where the expected  trend is estimated by using information from the whole time series), FO analysis can provide a different  perspective of recent change.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' For example, using a seven-years prediction, the FO analysis indicates  that there is a tendency in North Atlantic Sea SST towards a more negative trend than what should be  expected for the last 7 years of the time series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' We argue that the same interpretation is less evident  from an anomaly plot of the same time series (see Supplementary Fig 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Thus, while positive and  negative values indicate how observations deviate from a constant mean value in an anomaly plot, the  trend changes through time, making it harder to assess how the most recent observations deviate from  the trend that should be expected for these recent years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Recognizing that anomaly plots are important  for a large range of purposes within IEAs, we emphasize that FO analysis can provide useful additional  information for the practical work in IEA groups, in particular in the light of the challenge they are  often faced with of understanding and assessing the most recent development of an ecosystem [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Since the cumulative output of FO analysis also aim at giving a sweeping overview of the recent  dynamics of all the measured elements in an ecosystem by highlighting the variables that exhibit  unexpected change while at the same time showing trends and data for those that do not, the approach  should be useful for facilitating the necessary dialogue between scientists and stakeholders about recent  ecosystem change within the process of an IEA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Such overviews can also contribute to the scientific  output used to educate and inform the public and the political system during parts of policymaking  processes related to for example ecosystem-based management [56].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Acknowledgements  We would like to thank Benjamin Planque, who motivated us to consider this approach to analysing the  time series data compiled by the ICES integrated ecosystem assessment working groups and Mette  Mauritzen and Daniel Howell for comments on an earlier draft of the paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' This study was carried out  as part of the project “Sustainable multi-species harvest from the Norwegian Sea and adjacent  ecosystems”, funded by The Research Council of Norway (pr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' nr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 299554).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Working Group on the Integrated Assessments of the Norwegian Sea (WGINOR;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  outputs from 2020 meeting).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' ICES Scientific Reports.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' The second workshop on integrated trend analyses in support to integrated ecosystem  as-sessment (WKINTRA2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' ICES Scientific Reports.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' ICES WGINOR REPORT 2018 26-30 November 2018.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1016/0304-4076(95)01774-7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Whittaker E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' On a new method of graduation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Proceedings of the Edinburgh Mathematical  Society.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 1923;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='41:63-75.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' IEEE Transactions on Automatic  Control.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='19(6):716-23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1109/TAC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='1100705.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Kitagawa G, Gersch W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Journal of the American Statistical Association.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 1984;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' doi:  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='2307/2288279.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' PubMed PMID: WOS:A1984SW65000024.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Forecasting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Principles and practice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Melbourne: OTexts;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2018.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  MATLAB.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' ver.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  ICES.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  outputs from 2019 meeting).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Ocean Dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Working Group on Widely Distributed Stocks (WGWIDE).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  3:95.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 874 pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Mork KA, Skagseth Ø, Søiland H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Recent Warming and Freshening of the Norwegian Sea  Observed by Argo Data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Journal of Climate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2019;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='32(12):3695-705.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1175/jcli-d-18-0591.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  47.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Garcia T, Planque B, Arneberg P, Bogstad B, Skagseth Ø, Tiedemann M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' An appraisal of the  drivers of Norwegian spring-spawning herring (Clupea harengus) recruitment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='30(2):159-73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Miesner AK, Payne MR.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Oceanographic variability shapes the spawning distribution of blue  whiting (Micromesistius poutassou).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Fisheries Oceanography.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2018;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='27(6):623-38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi:  doi:10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' The North Atlantic subpolar gyre regulates the spawning  distribution of blue whiting (Micromesistius poutassou).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Canadian Journal of Fisheries and Aquatic  Sciences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2009;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='66(5):759-70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' PubMed PMID: WOS:000267811500005.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content=' Interim Report of the Working Group on Seasonal to Decadal Prediction of Marine  Ecosystems (WGS2D), 27–31 August 2018, ICES Headquarters, Copenhagen, Denmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' ICES CM  2018/EPDSG:22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 42 pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2018.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Samhouri JF, Andrews KS, Fay G, Harvey CJ, Hazen EL, Hennessey SM, et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  Ecosphere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='8(6):e01860.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1002/ecs2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1860.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='  Hardison S, Perretti CT, DePiper GS, Beet A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' A simulation study of trend detection methods  for integrated ecosystem assessment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' ICES Journal of Marine Science.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi:  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1093/icesjms/fsz097.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  West M, Harrison J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Bayesian Forecasting and Dynamic Models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' New York: Springer;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 1997.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Box G, Jenkins G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Time Series Analysis: Forecasting and Control.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' San Francisco: Holden-  Day;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 1970.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Bulgin CE, Merchant CJ, Ferreira D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Tendencies, variability and persistence of sea surface  temperature anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Scientific Reports.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='10(1):7986.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1038/s41598-020-64785-9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Cormier R, Kelble CR, Anderson MR, Allen JI, Grehan A, Gregersen O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Moving from  ecosystem-based policy objectives to operational implementation of ecosystem-based management  measures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Ices Journal of Marine Science.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='74(1):406-13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1093/icesjms/fsw181.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' PubMed  PMID: WOS:000397136400039.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Calculated log-likelihood (LL) and the optimum Q  by applying stochastic trend model for  2  d =  for the AMO and Norwegian Sea ecosystem datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Dataset  Variable  Q  Maximum log-  likelihood  AMO  AMOS  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='50  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='2  Norwegian Sea  ecosystem  (WGINOR)  RHC  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='05  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='8  RFW  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='08  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='6  NAO  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='05  161.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='3  ZooB  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='09  29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1  MacB  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='12  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='3  MacR  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='06  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1  MacW  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='07  44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1  MacL  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='07  71.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='8  HerB  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='06  125.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='7  HerR  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='05  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='6  HerW  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='11  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1  HerL  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='08  93.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='7  BWB  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='13  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='4  BWR  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='16  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='7  BWW  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='09  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='8  BWL  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='08  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='3  Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Averaged p-values and joint probability for the prediction and observation for  AMOS, RFW, ZooB, BWB, BWR, and BWW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  Year  AMOS  RFW  ZooB  BWB  BWR  BWW  2014  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='19  2015  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='14  2016  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='29  2017  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='42  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='22  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='12  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='13  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1003  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='12  2018  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='22  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='061  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='28  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='16  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1237  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='11  2019  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='28  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='023  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='13  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='29  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='1415  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='13  2020  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='42  Joint  probability  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='24e-05  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='06e-04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='0045  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='0063  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='0018  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='0016  Fig1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' Outline of proposed Flagged observation (FO) analysis  Time series data  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='5  Estimationof thetrend  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='5  Ecosystem-based  in the period 1950 - 2016  fisheries management  and  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  prediction of the data  contribution  in the period 2017-2019  1960  1970  1980  1990  2000  2010  12020  Yea  Dataintheperiod1950-2016  RealdataoutsideofFBs  deviatedfromrecent3-year  Estimated trend =(n)  trend - Flagged observation  17  RealdatawithinFBsfollowed  recent 3-year trend  Forecast bands (FBs)  y(n+jln)+2×/d(n+j|n)  1619  Prediction of the data  y(n+ jln), j=1, 2, 3  Fig 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The estimated three-years (upper) and seven-years (lower) prediction values of sea  surface temperature and the most recent observations for the dataset on the Atlantic  Multi-decadal Oscillation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The solid grey lines indicate the observations used for making  the forecast values and the black points indicate the observations that were plotted for  comparison with the prediction values (dotted blue line).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The dotted grey line presents  the prediction value  and the solid blue lines present the smoothed trend  estimates obtained by a fixed-interval smoother algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The band coloured by light-  blue presents the 95% FB, 80% and approximately 70% FBs, which upper and lower limits  were calculated by mean  ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='96 (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='28, 1) × standard deviation  ,  where  or  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content=' The observations in the years applying the prediction are  shown with black points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='8  1  1980  17  20  lyearelsius]  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='5  1980  06  0913  1619  [year]Climate:  Plankton:  Fig 3 Continued.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  RHC  225  wr  [108  20  15  10  5  0  5  10  15  1951  1619  [year]RFW  E  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='5  1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='5  2  1951  1619  [year]NAO  [djfm]  5  2  3  1907  1619  [year]ZooB  235  [gm-2  30  25  20  15  10  1995  16  19  [year]Pelagic fish:  Fig 3 Continued.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='  MacB  6  5  1  3  2  1  0  1980  1619  [year]X106  MacR  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='597  o!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='l  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='589  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='588  1980  1619  [vear]MacW  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+page_content='15  1980  16  19  [year]MacL  48  46  44  42  40  38  1963  16 19  [year]HerB  tonnes  45  40  [million t  35  30  25  20  15  10  5  1907  1619  [year]X108  HerR  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
+page_content='7868  O  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/8dE3T4oBgHgl3EQfRwni/content/2301.04426v1.pdf'}
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+A Critical Appraisal of Data Augmentation Methods
+for Imaging-Based Medical Diagnosis Applications
+Tara M. Pattilachan∗¶, Ugur Demir†¶, Elif Keles†, Debesh Jha†, Derk Klatte‡, Megan Engels‡,
+Sanne Hoogenboom‡, Candice Bolan‡, Michael Wallace§, Ulas Bagci†
+∗University of Central Florida, FL, USA,
+†Machine and Hybrid Intelligence Lab, Northwestern University, IL, USA,
+‡ Mayo Clinic, Jacksonville, FL, USA,
+§ Mayo Clinic, Sheikh Shakhbout Medical City, UAE
+Abstract—Current data augmentation techniques and trans-
+formations are well suited for improving the size and quality
+of natural image datasets but are not yet optimized for medical
+imaging. We hypothesize that sub-optimal data augmentations
+can easily distort or occlude medical images, leading to false
+positives or negatives during patient diagnosis, prediction, or
+therapy/surgery evaluation. In our experimental results, we found
+that utilizing commonly used intensity-based data augmentation
+distorts the MRI scans and leads to texture information loss,
+thus negatively affecting the overall performance of classification.
+Additionally, we observed that commonly used data augmenta-
+tion methods cannot be used with a plug-and-play approach in
+medical imaging, and requires manual tuning and adjustment.
+Index Terms—Augmentation, diagnosis, deep learning, IPMN
+I. INTRODUCTION
+In this study, we investigate how commonly used data
+augmentation methods affect medical imaging based diagnosis
+tasks, the following methods are used: RandAugment [1],
+AutoAugment [2], Fast AutoAugment [3], Trivial Augment [4]
+and AugMix [5].
+Fig. 1. Overall architecture for ResNeST [6] training with data augmentation.
+II. METHOD
+Figure 1 shows the block diagram of the proposed method.
+In this study, we tested commonly used data augmentation
+methods RandAugment [1], AutoAugment [2], Fast AutoAug-
+ment [3], Trivial Augment [4] and AugMix [5], and their
+impact on the MRI based IPMN classification problem. The
+classification problem was modelled via a deep learning archi-
+tecture, called ResNeST [6], where we classified the images
+into normal, low grade and high grade categories.
+A. Results
+Table I exhibits the performance of each augmentation
+method and the baseline. It can be observed that the baseline
+TABLE I
+MRI BASED IPMN CLASSIFICATION RESULTS WITH RESPECT TO DATA
+AUGMENTATION METHODS.
+.
+Method
+Accuracy
+Baseline
+61.70% ± 9.42
+RandAug
+55.30% ± 9.29
+RandAug - geometric
+61.67% ± 8.37
+Auto Augment
+51.03% ± 10.31
+Fast Auto Augment
+55.34% ± 12.78
+Trivial Augment
+51.75% ± 9.30
+AugMix
+54.56% ± 8.19
+achieves an accuracy of 61.70% ± 9.42. However, other
+augmentation methods such as RandAug, Auto Augment, Fast
+Auto Augment, Trivial Augment and AugMix are causing
+significant performance drop (refer Table I). Table shows
+that when the intensity based augmentation is removed per-
+formance stays close to the baseline in the “RandAug -
+geometric” experiments where it achieves 61.67% ± 8.37.
+III. CONCLUSION
+In this study, we raised critical appraisals for the role of
+data augmentation for medical imaging tasks. We analyzed five
+commonly used data augmentation approaches and their effect
+on the performance of the MRI based IPMN classification
+problem. Our study in the controlled experiments showed that
+the commonly used data augmentation methods are designed
+specifically for natural images and they can have adverse
+effects in medical diagnosis tasks if used without modification.
+Acknowledgement: This project is supported by the NIH
+funding: R01-CA246704 and R01-CA240639.
+REFERENCES
+[1] E. D. Cubuk, B. Zoph, J. Shlens, and Q. Le, “Randaugment: Practical au-
+tomated data augmentation with a reduced search space,” in Proceedings
+of the Advances in NIPS, vol. 33, 2020, pp. 18 613–18 624.
+[2] E. D. Cubuk, B. Zoph, D. Mane, V. Vasudevan, and Q. V. Le, “Autoaug-
+ment: Learning augmentation policies from data,” in Proceedings of the
+CVPR, 2019.
+[3] S. Lim, I. Kim, T. Kim, C. Kim, and S. Kim, “Fast autoaugment,” in
+Proceedings of the NIPS, vol. 32, 2019.
+[4] S. G. M¨uller and F. Hutter, “Trivialaugment: Tuning-free yet state-of-the-
+art data augmentation,” in Proceedings of the ICCV, 2021, pp. 774–782.
+[5] D. Hendrycks*, N. Mu*, E. D. Cubuk, B. Zoph, J. Gilmer, and B. Lak-
+shminarayanan, “Augmix: A simple method to improve robustness and
+uncertainty under data shift,” in Proceedings of the ICLR, 2020.
+[6] H. Zhang, C. Wu, Z. Zhang, Y. Zhu, Z. Zhang, H. Lin, Y. Sun, T. He,
+J. Muller, R. Manmatha, M. Li, and A. Smola, “Resnest: Split-attention
+networks,” arXiv preprint arXiv:2004.08955, 2020.
+arXiv:2301.02181v1  [eess.IV]  14 Dec 2022
+
+Input
+Augmented Input
+Normal
+LowGrade
+Data
+ResNeST
+Augmentation
+High Grade
+..
\ No newline at end of file
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+page_content='A Critical Appraisal of Data Augmentation Methods  for Imaging-Based Medical Diagnosis Applications  Tara M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Pattilachan∗¶,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Ugur Demir†¶,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Elif Keles†,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Debesh Jha†,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Derk Klatte‡,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Megan Engels‡,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  Sanne Hoogenboom‡,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Candice Bolan‡,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Michael Wallace§,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Ulas Bagci†  ∗University of Central Florida,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' FL,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' USA,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  †Machine and Hybrid Intelligence Lab,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Northwestern University,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' IL,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' USA,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  ‡ Mayo Clinic,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Jacksonville,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' FL,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' USA,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  § Mayo Clinic,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Sheikh Shakhbout Medical City,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' UAE  Abstract—Current data augmentation techniques and trans-  formations are well suited for improving the size and quality  of natural image datasets but are not yet optimized for medical  imaging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' We hypothesize that sub-optimal data augmentations  can easily distort or occlude medical images, leading to false  positives or negatives during patient diagnosis, prediction, or  therapy/surgery evaluation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' In our experimental results, we found  that utilizing commonly used intensity-based data augmentation  distorts the MRI scans and leads to texture information loss,  thus negatively affecting the overall performance of classification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  Additionally, we observed that commonly used data augmenta-  tion methods cannot be used with a plug-and-play approach in  medical imaging, and requires manual tuning and adjustment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  Index Terms—Augmentation, diagnosis, deep learning, IPMN  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' INTRODUCTION  In this study, we investigate how commonly used data  augmentation methods affect medical imaging based diagnosis  tasks, the following methods are used: RandAugment [1],  AutoAugment [2], Fast AutoAugment [3], Trivial Augment [4]  and AugMix [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Overall architecture for ResNeST [6] training with data augmentation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' METHOD  Figure 1 shows the block diagram of the proposed method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  In this study, we tested commonly used data augmentation  methods RandAugment [1], AutoAugment [2], Fast AutoAug-  ment [3], Trivial Augment [4] and AugMix [5], and their  impact on the MRI based IPMN classification problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' The  classification problem was modelled via a deep learning archi-  tecture, called ResNeST [6], where we classified the images  into normal, low grade and high grade categories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Results  Table I exhibits the performance of each augmentation  method and the baseline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' It can be observed that the baseline  TABLE I  MRI BASED IPMN CLASSIFICATION RESULTS WITH RESPECT TO DATA  AUGMENTATION METHODS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  Method  Accuracy  Baseline  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='70% ± 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='42  RandAug  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='30% ± 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='29  RandAug - geometric  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='67% ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='37  Auto Augment  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='03% ± 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='31  Fast Auto Augment  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='34% ± 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='78  Trivial Augment  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='75% ± 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='30  AugMix  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='56% ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='19  achieves an accuracy of 61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='70% ± 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' However, other  augmentation methods such as RandAug, Auto Augment, Fast  Auto Augment, Trivial Augment and AugMix are causing  significant performance drop (refer Table I).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Table shows  that when the intensity based augmentation is removed per-  formance stays close to the baseline in the “RandAug -  geometric” experiments where it achieves 61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='67% ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' CONCLUSION  In this study, we raised critical appraisals for the role of  data augmentation for medical imaging tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' We analyzed five  commonly used data augmentation approaches and their effect  on the performance of the MRI based IPMN classification  problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Our study in the controlled experiments showed that  the commonly used data augmentation methods are designed  specifically for natural images and they can have adverse  effects in medical diagnosis tasks if used without modification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  Acknowledgement: This project is supported by the NIH  funding: R01-CA246704 and R01-CA240639.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
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+page_content=' Manmatha, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Li, and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content=' Smola, “Resnest: Split-attention  networks,” arXiv preprint arXiv:2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='08955, 2020.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='02181v1  [eess.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='IV]  14 Dec 2022  Input  Augmented Input  Normal  LowGrade  Data  ResNeST  Augmentation  High Grade  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
+page_content='.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/AtE0T4oBgHgl3EQfPgDv/content/2301.02181v1.pdf'}
diff --git a/BdE1T4oBgHgl3EQfVgTd/content/tmp_files/2301.03104v1.pdf.txt b/BdE1T4oBgHgl3EQfVgTd/content/tmp_files/2301.03104v1.pdf.txt
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+arXiv:2301.03104v1  [math.AG]  8 Jan 2023
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+ANGELO FELICE LOPEZ* AND DEBADITYA RAYCHAUDHURY**
+Abstract. We study varieties X ⊆ PN of dimension n such that TX(k) is an Ulrich vector bundle for
+some k ∈ Z. First we give a sharp bound for k in the case of curves. Then we show that k ≤ n + 1 if
+2 ≤ n ≤ 12. We classify the pairs (X, OX(1)) for k = 1 and we show that, for n ≥ 4, the case k = 2
+does not occur.
+1. Introduction
+Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. As is well known, the study of
+vector bundles on X can give important geometrical information about X itself. Regarding this, one
+of the most interesting family of vector bundles associated to X and its embedding, that received a lot
+of attention lately, is that of Ulrich vector bundles, that is bundles E such that Hi(E(−p)) = 0 for all
+i ≥ 0 and 1 ≤ p ≤ n. The study of such bundles is closely related with several areas of commutative
+algebra and algebraic geometry, and often gives interesting consequences on the geometry of X and on
+the cohomology of sheaves on X (see for example in [ES, Be1, CMRPL] and references therein).
+Perhaps the most challenging question in these matters is whether every X ⊆ PN carries an Ulrich
+vector bundle (see for example [ES, page 543]). It comes therefore very natural to ask if usual vector
+bundles associated to X can be Ulrich. Also, since Ulrich vector bundles are globally generated, it is
+better to consider twisted versions of the usual bundles associated to X. The cases of the (twisted)
+normal, cotangent, restricted tangent and cotangent bundles have been dealt with in [Lop], with an
+essentially complete classification.
+In this paper we study the more delicate question: for which integers k one has that TX(k) is an
+Ulrich vector bundle?
+Ulrich vector bundles have special cohomological features, but also numerical ones. This makes the
+above question rather tricky. It is easy to show that k ≥ 0 unless (X, OX(1), k) = (P1, OP1(1), −2).
+In the case k = 0, a recent result [BMPT, Prop. 4.1, Thm. 4.5] gives a classification: (X, OX(1)) =
+(P1, OP1(3)), (P2, OP2(2)) (we will give a new and simple proof in section 8; another proof is given in
+[C2]). On the other hand, for k ≥ 1, the question is more subtle as we will see below.
+In the case of curves, one sees that k = 1 is not possible (see Lemma 4.3(i)), while the cases k = 2, 3
+can be dealt with on any curve (see Lemma 5.1 and Example 5.2). On the other hand, the following
+sharp bound holds, showing that for curves k can be as large as wanted.
+Theorem 1.
+Let X ⊆ PN be a smooth irreducible curve of genus g. If TX(k) is an Ulrich line bundle, then
+(1.1)
+k ≤
+√8g + 1 − 1
+2
+and equality holds if and only if k is even and either X is one of the curves (5.1) lying on a smooth
+cubic or X is a curve of type (k
+2 +1, k +2) on a smooth quadric. Also, in both cases, TX(k) is an Ulrich
+line bundle, hence the bound is sharp for every even k ≥ 0. Moreover, if X has general moduli, then
+k ≤ 4.
+As far as we know, only curves show this kind of behavior, meaning that k is not bounded in terms
+of the dimension (a somewhat bad bound can also be given in terms of the degree, see Lemma 4.7). As
+supporting evidence, we prove the following
+* Research partially supported by PRIN “Advances in Moduli Theory and Birational Classification”, GNSAGA-INdAM
+and the MIUR grant Dipartimenti di Eccellenza 2018-2022.
+** Research partially supported by a Simons Postdoctoral Fellowship from the Fields Institute for Research in Mathe-
+matical Sciences.
+Mathematics Subject Classification : Primary 14J60. Secondary 14J35, 14J40.
+1
+
+2
+A.F. LOPEZ, D. RAYCHAUDHURY
+Theorem 2.
+Let X ⊆ PN be a smooth irreducible variety of dimension n such that 2 ≤ n ≤ 12. If TX(k) is an
+Ulrich vector bundle, then k ≤ n + 1.
+We should point out that, for n ≥ 2, we know no examples with k ≥ 2 and only one example with
+k = 1. As a matter of fact, the case k = 1 can be completely characterized, as follows
+Theorem 3.
+Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Then TX(1) is an Ulrich vector
+bundle if and only if (X, OX(1)) = (S5, −2KS5), where S5 is a Del Pezzo surface of degree 5.
+On the other hand, for k = 2, we have
+Theorem 4.
+Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 4. Then TX(2) is not an Ulrich vector
+bundle.
+We do not know what happens for k = 2, n = 3, even though some evidence suggests that it might
+not be possible. Also, for surfaces, the cases k = 2, 3 point out to the possible existence, that needs to be
+further investigated, of some minimal surfaces of general type, as shown in Lemma 6.1 and Proposition
+6.2.
+Finally, in any dimension, another interesting case is the one in which ωX and OX(1) are numerically
+proportional. This is dealt with in Theorem 4.10, Corollaries 4.11 and 4.12.
+2. Notation
+Throughout the paper we work over the complex numbers. Moreover we henceforth establish the
+following
+Notation 2.1.
+• X is a smooth irreducible variety of dimension n ≥ 1.
+• H is a very ample divisor on X.
+• For any sheaf G on X we set G(l) = G(lH).
+• d = Hn is the degree of X.
+• C is a general curve section of X under the embedding given by H.
+• S is a general surface section of X under the embedding given by H, when n ≥ 2
+• g = g(C) = 1
+2[KXHn−1 + (n − 1)d] + 1 is the sectional genus of X.
+• For 1 ≤ i ≤ n − 1, let Hi ∈ |H| be general divisors and set Xn := X and Xi = H1 ∩ · · · ∩ Hn−i.
+3. Generalities on Ulrich bundles
+We collect some well-known facts, to be used sometimes later.
+Definition 3.1. Let E be a vector bundle on X. We say that E is an Ulrich vector bundle for (X, H)
+if Hi(E(−p)) = 0 for all i ≥ 0 and 1 ≤ p ≤ n.
+We have
+Lemma 3.2. Let E be a rank r Ulrich vector bundle for (X, H). Then
+(i) c1(E)Hn−1 = r
+2[KX + (n + 1)H]Hn−1,
+(ii) If n ≥ 2, then c2(E)Hn−2 = 1
+2[c1(E)2 − c1(E)KX]Hn−2 + r
+12[K2
+X + c2(X) − 3n2+5n+2
+2
+H2]Hn−2.
+(iii) χ(E(m)) = rd
+n!(m + 1) · · · (m + n).
+(iv) Hn(E(m)) = 0 if and only if m ≥ −n.
+(v) E∗(KX + (n + 1)H) is also an Ulrich vector bundle for (X, H).
+(vi) E is globally generated.
+(vii) h0(E) = rd.
+(viii) E is arithmetically Cohen-Macaulay (aCM), that is Hi(E(j)) = 0 for 0 < i < n and all j ∈ Z.
+(ix) E|Y is Ulrich on a smooth hyperplane section Y of X.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+3
+Proof. We have
+(3.1)
+KXi = (KX + (n − i)H)|Xi , 1 ≤ i ≤ n.
+By [CH, Lemma 2.4(iii)] we have that
+c1(E)Hn−1 = deg(E|C) = r(d + g − 1)
+and using (3.1) on C = X1 we have
+KXHn−1 = 2(g − 1) − (n − 1)d
+thus giving (i). To see (ii) observe that the exact sequences, for 1 ≤ i ≤ n − 1,
+0 → TXi → (TXi+1)|Xi → H|Xi → 0
+and (3.1) give by induction that
+(3.2)
+c2(S) = c2(X2) = c2(X)Hn−2 + (n − 2)KXHn−1 +
+�n − 1
+2
+�
+d.
+It follows from [C1, Prop. 2.1(2.2)], (3.1), and Noether’s formula 12χ(OS) − K2
+S = c2(S) that
+c2(E)Hn−2
+= 1
+2[c1(E)2 − c1(E)(KX + (n − 2)H)]Hn−2 − r
+�
+Hn − [KX+(n−2)]2Hn−2+c2(S)
+12
+�
+=
+= 1
+2[c1(E)2 − c1(E)KX]Hn−2 − n−2
+2 c1(E)Hn−1 − r
+�
+Hn − [KX+(n−2)H]2Hn−2+c2(S)
+12
+�
+Now (ii) follows from the above equation by using (i) and (3.2). Next, (iii) is [CH, Lemma 2.6]. To see
+(iv) observe that E is 0-regular, hence it is q-regular for every q ≥ 0 and therefore Hn(E(q − n)) = 0,
+that is (iv). Also, (v) follows by definition and Serre duality, while (vi) follows by definition, since E is
+0-regular, and [Laz, Thm. 1.8.5]. For (vii), (viii) and (ix) see [ES, Prop. 2.1] (or [Be1, (3.1)]) and [Be1,
+(3.4)].
+□
+4. TX(k) Ulrich in any dimension
+We start by drawing some consequences on (X, H, k), of cohomological and numerical type, when
+TX(k) is an Ulrich vector bundle.
+Lemma 4.1. Let (X, H) = (Pn, OPn(1)), n ≥ 1. Then TX(k) is an Ulrich vector bundle if and only if
+n = 1 and k = −2.
+Proof. The assertion is obvious if (X, H, k) = (P1, OP1(1), −2). Vice versa suppose that TX(k) is an
+Ulrich vector bundle.
+If (X, H) = (Pn, OPn(1)), it follows by [ES, Prop. 2.1] (or [Be1, Thm. 2.3])
+that TPn(k) ∼= O⊕n
+Pn , hence 0 = det(TPn(k)) = OPn(nk + n + 1), so that 1 = −n(k + 1), giving
+n = 1, k = −2.
+□
+Lemma 4.2. (cohomological conditions)
+Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. If TX(k) is an Ulrich vector bundle
+we have:
+(i) Either (X, H, k) = (P1, OP1(1), −2), or k ≥ 0.
+(ii) If n ≥ 2, then TX is aCM, that is Hi(TX(j)) = 0 for 1 ≤ i ≤ n − 1 and for every j ∈ Z. In
+particular Hi(TX) = 0 for 1 ≤ i ≤ n − 1.
+(iii) If k ≥ 1, then H0(TX) = 0, hence X has discrete automorphism group.
+(iv) If n ≥ 2, then X is infinitesimally rigid, that is H1(TX) = 0.
+(v) H0(KX + (n − k − 2)H) = 0 and, if n ≥ 2, also H0(KX + (n − k − 1)H) = 0.
+(vi) If q(X) ̸= 0 then H0(KX + (n − k)H) = 0.
+(vii) If k ≤ n − 1, then pg(X) = 0.
+(viii) Let a(X, H) = min{l ∈ Z : lH − KX ≥ 0}. Then k ≤ a(X,H)(n+2)
+2n
++ n+1
+2 .
+Moreover H0((⌈n(2k−n−1)
+n+2
+⌉ − 1)H − KX) = 0.
+(ix) KX − kH is not big.
+
+4
+A.F. LOPEZ, D. RAYCHAUDHURY
+Proof. Since TX(k) is an Ulrich vector bundle, it is globally generated by Lemma 3.2(vi).
+Now if
+k ≤ −1 we would have that 0 ̸= H0(TX(k)) ⊆ H0(TX(−1)).
+But then the Mori-Sumihiro-Wahl’s
+theorem [MS, Thm. 8], [W, Thm. 1] implies that (X, H) = (P1, OP1(2)), (Pn, OPn(1)).
+In the first
+case we have that 0 = Hi(TP1(k − 1)) = Hi(OP1(2k)) = 0 for i ≥ 0, a contradiction. In the second
+case apply Lemma 4.1. This proves (i). Now (ii) follows by Lemma 3.2(viii). If k ≥ 1 we have that
+H0(TX) ⊆ H0(TX(k − 1)) = 0, hence (iii). (iv) is implied by (ii). As for (v), recall that, as is well
+known, Ω1
+X(2) is globally generated. Now if H0(KX + (n − k − 2)H) ̸= 0 then we get the contradiction
+0 ̸= H0(Ω1
+X(2)) ⊆ H0(Ω1
+X(KX + (n − k)H)) = Hn(TX(k − n))∗ = 0.
+This gives the first part of (v). Similarly, if q(X) ̸= 0 and H0(KX + (n − k)H) ̸= 0 then we get the
+contradiction
+0 ̸= H0(Ω1
+X) ⊆ H0(Ω1
+X(KX + (n − k)H)) = Hn(TX(k − n))∗ = 0.
+This gives (vi). Now if n ≥ 2, consider Y ∈ |H| smooth. Then TX(k)|Y is an Ulrich vector bundle on
+Y by Lemma 3.2(ix), hence Hn−1(TX(k − n + 1)|Y ) = 0. Now the exact sequence
+0 → TY (k − n + 1) → TX(k − n + 1)|Y → OY (k − n + 2) → 0
+implies that Hn−1(OY (k − n + 2)) = 0. Hence, setting L = KX + (n − k − 1)H, we get by Serre’s
+duality that
+H0(L|Y ) = H0(KY + (n − k − 2)H|Y ) = 0.
+Therefore H0(L(−l)|Y ) = 0 for every l ≥ 0 and the exact sequences
+0 → L(−l − 1) → L(−l) → L(−l)|Y → 0
+show that h0(L(−l − 1)) = h0(L(−l)) for every l ≥ 0. Since this is zero for l ≫ 0, we get that they
+are all zero, hence H0(KX + (n − k − 1)H) = 0. This proves the second part of (v). Now, to see (vii),
+suppose that k ≤ n − 1. If n ≥ 2, we see that (v) gives H0(KX) ⊆ H0(KX + (n − k − 1)H) = 0,
+hence (vii). If n = 1 we have that k ≤ 0, hence X = P1 by (i) and Lemma 4.3(i). Observe that
+a(X, H)H − KX ≥ 0, hence (a(X, H)H − KX)Hn−1 ≥ 0 and using Lemma 4.3(ii), we get
+a(X, H) ≥ n(2k − n − 1)
+n + 2
+This gives (viii) since, by its own definition, H0((a(X, H) − 1)H − KX) = 0. Finally assume that
+KX − kH is big. Then Serre’s duality gives H0(TX(k)) = Hn(Ω1
+X(KX − kH))∗ = 0 by Bogomolov-
+Sommese vanishing [Bo, Thm. 4], contradicting Lemma 3.2(vi).
+□
+Lemma 4.3. (numerical conditions)
+Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. If TX(k) is an Ulrich vector bundle
+we have:
+(i) d = (n+2)(g−1)
+nk−1
+. In particular either (X, H, k) = (P1, OP1(1), −2), or g = k = 0, or g ≥ 2.
+(ii) k = n+1
+2
++
+� n+2
+2nd
+�
+KXHn−1; equivalently KXHn−1 = n(2k−n−1)
+n+2
+d.
+(iii) If k < n+1
+2 , then X is rationally connected and Hi(OX) = 0 for every i ≥ 1.
+(iv) If k > n+1
+2 , then −KX is not pseff.
+(v) TX is semistable.
+(vi) If n ≥ 2, then K2
+XHn−2 ≤
+2n
+n−1c2(X)Hn−2.
+(vii) If n ≥ 2, then
+(12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 2(n + 12)K2
+XHn−2 + 2(n − 12)c2(X)Hn−2 = 0.
+Proof. Since c1(TX(k)) = −KX + nkH, we get by Lemma 3.2(i) that
+(−KX + nkH)Hn−1 = n
+2
+�
+KXHn−1 + (n + 1)d
+�
+and this gives (ii). Also, using KXHn−1 = 2(g − 1) − (n − 1)d, we get that
+(nk − 1)d = (n + 2)(g − 1).
+Now if nk − 1 = 0 then n = k = g = 1, but then TX(k) = OX(1) is not Ulrich. Therefore nk − 1 ̸= 0
+and d = (n+2)(g−1)
+nk−1
+. Hence g ̸= 1 and if g = 0 then either k = 0 or k ̸= 0 and in the latter case we
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+5
+have that nk < 1, hence (X, H, k) = (P1, OP1(1), −2) by Lemma 4.2(i). This proves (i). Next, (v)
+follows since Ulrich vector bundles are semistable by [CH, Thm. 2.9], hence Bogomolov’s inequality
+gives (vi). To see (iii), suppose that k < n+1
+2 . If n ≥ 2, then (ii) gives that KXHn−1 < 0, hence X is
+rationally connected by (v) and [BMQ, Main Thm.] (see also [CP, Thm. 1.1]). Hence, as is well known,
+Hi(OX) = 0 for every i ≥ 1. If n = 1 then k ≤ 0 and X = P1 by (i). Thus we get (iii). If k > n+1
+2 ,
+then either n = 1 and g ≥ 2 by (i), so that −KX is not pseff, or n ≥ 2 and (ii) gives that KXHn−1 > 0,
+hence again −KX is not pseff and we get (iv). To see (vii), observe that
+(4.1)
+c2(TX(k))Hn−2 = c2(X)Hn−2 − k(n − 1)KXHn−1 +
+�n
+2
+�
+k2d.
+From Lemma 3.2(ii), we get
+(4.2)
+c2(TX(k))Hn−2 =
+�n2k2
+2
+− n
+24
+�
+3n2 + 5n + 2
+��
+d−3nk
+2 KXHn−1+
+�
+1 + n
+12
+�
+K2
+XHn−2+ n
+12c2(X)Hn−2.
+Combining (4.1), (4.2) and (ii), we obtain (vii).
+□
+Definition 4.4. For n ≥ 1 we denote by Qn a smooth quadric in Pn+1.
+Lemma 4.5. Let (X, H) = (Qn, OQn(1)), n ≥ 1. Then TX(k) is not an Ulrich vector bundle for any
+integer k.
+Proof. Since g = 0, it follows by Lemma 4.3(i) that k = 0 and 2 = d = n + 2, a contradiction.
+□
+We will use the nef value of (X, H):
+(4.3)
+τ(X, H) = min{t ∈ R : KX + tH is nef}.
+We observe that in [BS, Def. 1.5.3] the nef value is defined only when KX is not nef. On the other
+hand, it makes sense and it will be used, throughout this paper, also when KX is nef.
+A very useful observation is the following.
+Lemma 4.6. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. If TX(k) is an Ulrich
+vector bundle, then Ω1
+Y (KX |Y +(n+1−k)H|Y ) is globally generated for any smooth subvariety Y ⊆ X.
+Moreover:
+(i) If ±(KX + n(n+1−2k)
+n+2
+H) is pseff, then KX ≡ n(2k−n−1)
+n+2
+H.
+(ii) τ(X, H) ≥ n(n+1−2k)
+n+2
+.
+(iii) τ(X, H) ≤ n −
+nk
+n+1. In particular, if KX is not nef, then k ≤ n.
+(iv) If k ≥ n + 1, then KX is ample.
+Proof. Note that Ω1
+X(KX + (n + 1 − k)H) is Ulrich and globally generated by Lemma 3.2(v) and (vi).
+Since Ω1
+X(KX + (n + 1 − k)H) surjects onto Ω1
+Y (KX |Y + (n + 1 − k)H|Y ), the latter is also globally
+generated. Moreover so is det(Ω1
+X(KX+(n+1−k)H) = (n+1)KX+n(n+1−k)H, hence we get (iii) and,
+if k ≥ n+2, we also deduce that KX is ample. On the other hand, if k = n+1, then Ω1
+X(KX) is Ulrich,
+and we claim that det(Ω1
+X(KX)) = (n + 1)KX is ample. In fact, if not, then [LS, Thm. 1] implies that
+there is a line L ⊂ X such that Ω1
+X(KX)|L is trivial. Hence (n + 1)KX · L = deg(Ω1
+X(KX)|L) = 0. But
+then we have a surjection Ω1
+X(KX)|L → Ω1
+L, contradicting the fact that Ω1
+L is not globally generated.
+This proves (iv). As for (i) and (ii), set q = n(n+1−2k)
+n+2
+, so that (KX + qH)Hn−1 = 0 by Lemma 4.3(ii).
+Now if ±(KX + qH) is pseff, then KX + qH ≡ 0 by [FL2, Cor. 3.15] (see also [FL1, Prop. 3.7]), thus
+proving (i). Also, (i) implies that either KX ≡ −qH and then τ(X, H) = q, or KX + qH is not pseff,
+hence not nef. Therefore, in the latter case, τ(X, H) > q, proving (ii).
+□
+Lemma 4.7. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. If TX(k) is an Ulrich
+vector bundle we have that
+k ≤ (n + 2)(d − 4) + 4
+4n
+.
+Proof. We have X ⊂ PH0(H) = PN. If N = n then (X, H) = (Pn, OPn(1)) and Lemma 4.1 gives that
+n = 1 and k = −2. Since d = 1 we have that k = −2 ≤ − 5
+4 = (n+2)(d−4)+4
+4n
+.
+
+6
+A.F. LOPEZ, D. RAYCHAUDHURY
+We now show that it cannot be that N = n + 1. Assume that N = n + 1, so that d ≥ 2. If n = 1 we
+have that KX = (d − 3)H, g =
+�d−1
+2
+�
+and k = 3(d−3)
+2
++ 1 by Lemma 4.3(i). Now 0 = H0(TX(k − 1)) =
+H0((−d + 2 + k)H) and therefore −d + 2 + k ≤ −1, giving the contradiction d ≤ 1. Hence n ≥ 2 and
+since C ⊂ P2 we have that g − 1 = d(d−3)
+2
+and Lemma 4.3(i) implies that d = 2(nk−1)
+n+2
++ 3. On the other
+hand Lemma 4.2(v) gives that
+0 = H0(KX + (n − k − 1)H) = H0((d − k − 3)H)
+and therefore
+2(nk − 1)
+n + 2
+− k ≤ −1
+that is k(n − 2) + n ≤ 0, a contradiction.
+Therefore N ≥ n + 2 and C ⊂ PN−n+1 can be projected isomorphically to a non-degenerate smooth
+irreducible curve in P3. Then Castelnuovo’s bound gives that g − 1 ≤ d(d−4)
+4
+and Lemma 4.3(ii) implies
+the required bound on k.
+□
+A nice consequence of the above lemmas is the following.
+Proposition 4.8. There does not exist any (X, H, k) with TX(k) an Ulrich vector bundle, when:
+(i) KX ≡ 0.
+(ii) ±KX is pseff and k = n+1
+2 .
+Proof. Under hypothesis (ii), we get from Lemma 4.6(i) that KX ≡ 0. Thus we will be done if we prove
+(i). Assume next that KX ≡ 0, so that k = n+1
+2
+by Lemma 4.3(ii) and n ≥ 3 by Lemma 4.3(i). Since
+H − KX is ample, it follows by Kodaira vanishing that Hi(H) = Hi(KX + H − KX) = 0 for i > 0,
+hence
+h0(KX + H) = χ(KX + H) = χ(H) = h0(H) ̸= 0.
+On the other hand, Lemma 4.2(v) gives that h0(KX + n−3
+2 H) = 0, whence, if n ≥ 5, we get the
+contradiction h0(KX + H) = 0.
+It remains to consider the case n = 3, k = 2. Note that pg(X) = 0 by Lemma 4.2(vii) and q(X) = 0,
+for otherwise Lemma 4.2(vi) gives that h0(KX + H) = 0. Therefore χ(OX) ≥ 1. On the other hand
+χ(OX) =
+1
+24c1(X)c2(X) = 0, a contradiction.
+□
+We now prove Theorem 2.
+Proof of Theorem 2. By the Hodge index theorem we have that H2
+|SK2
+S ≤ (H|SKS)2, that is
+(4.4)
+dK2
+XHn−2 ≤ (KXHn−1)2.
+Using Lemma 4.3(vi), (vii) and (4.4) we obtain that
+0 = (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 2(n + 12)K2
+XHn−2 + 2(n − 12)c2(X)Hn−2 ≤
+≤ (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 3n2 + 11n + 12
+n
+K2
+XHn−2 ≤
+≤ (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 3n2 + 11n + 12
+nd
+(KXHn−1)2
+which, using Lemma 4.3(ii) becomes
+4nk2 − 4n(n + 1)k − 3n2 − 7n − 4 ≤ 0
+giving
+k ≤ n2 + n +
+√
+n4 + 5n3 + 8n2 + 4n
+2n
+< n + 2.
+□
+The case k = 0 is known:
+Theorem 4.9. ([BMPT, Prop. 4.1, Thm. 4.5])
+Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Then TX is an Ulrich vector bundle
+if and only if (X, H) = (P1, OP1(3)), (P2, OP2(2)).
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+7
+We will give a quick alternative proof in section 8.
+Next we study the case when KX and H are proportional.
+Theorem 4.10. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Suppose that the
+numerical classes of H and KX are proportional and that either
+(i) 1 ≤ n ≤ 11 and either k ≤ n+1
+2
+or k ≥ n + 2; or
+(ii) n = 12, or
+(iii) n ≥ 13 and k ̸∈ {n + 2, n + 3}.
+Then TX(k) is Ulrich if and only if (X, H, k) is one of the following:
+(1) (P1, OP1(1), −2),
+(2) (P1, OP1(3), 0),
+(3) (P2, OP2(2), 0),
+(4) (S5, −2KS5, 1), where S5 is a Del Pezzo surface of degree 5.
+Proof. In the cases (1)-(4) we have that TX(k) is Ulrich by Lemma 4.3(i), Theorem 4.9 and Theorem
+6.3.
+Vice versa, suppose that the numerical classes of H and KX are proportional and that we are under
+one of hypotheses (i), (ii) or (iii) and that TX(k) is Ulrich.
+Observe that, since N 1(X) is a torsion free finitely generated abelian group, we can find an ample
+primitive divisor A and some r, s ∈ Z such that s > 0, H ≡ sA and KX ≡ −rA. In particular, Lemma
+4.3(ii) gives
+(4.5)
+r(n + 2) = n(n + 1 − 2k)s.
+If k ≤ 0 we are in cases (1)-(3) by Lemma 4.2(i) and Theorem 4.9. Hence assume that k ≥ 1. Note
+that Proposition 4.8 shows that k ̸= n+1
+2 .
+If (ii) or (iii) holds, since the numerical classes of H and KX are proportional, Lemma 4.3(vi), (ii)
+and (vii) imply that
+4nk2 − 4n(n + 1)k − 3n2 − 7n − 4 ≥ 0
+so that k > n + 1. This is a contradiction under hypothesis (ii) by Theorem 2. Under hypothesis (iii),
+we get that k ≥ n + 4. Then it follows by (4.5) that
+−r − ks = (n − 2)k − n2 − n
+n + 2
+s ≥ n − 8
+n + 2s > 0
+hence KX − kH = (−r − ks)A is ample, contradicting Lemma 4.2(ix). Thus it remains to consider
+hypothesis (i).
+Now assume (i), so that n ≥ 2 and Theorem 2 implies that it cannot be that k ≥ n + 2. Hence
+k < n+1
+2
+and Lemma 4.3(ii) implies that X is Fano. Consequently, the numerical and linear equivalence
+for divisors coincide on X and then KX = −rA and H = sA. We can also assume that r ≤ n − 1, for
+otherwise, as is well known, (X, H) = (Pn, OPn(1)), (Qn, OQn(1)), contradicting Lemmas 4.1 and 4.5.
+Next, set PA(t) := χ(KX + tA), so that PA(t) = h0(KX + tA) whenever t ≥ 1 is an integer. By
+Riemann-Roch (see for example [Ho, eq. (1), p. 2], we have
+(4.6)
+PA(t) = An
+n! tn + An−1KX
+2(n − 1)!tn−1 + An−2(K2
+X + c2(X))
+12(n − 2)!
+tn−2 + · · · + (−1)nχ(OX).
+Note that n is even, for otherwise n and n + 2 are coprime, and consequently n divides r by (4.5),
+hence r ≥ n, a contradiction.
+Set n = 2m, where 1 ≤ m ≤ 5.
+If m = 1 we have that n = 2, k = 1 and we are in case (4) by Theorem 6.3.
+We will now exclude the remaining cases for m.
+Note that we can rewrite (4.5) as
+(4.7)
+(m + 1)r = m(2m − 2k + 1)s.
+Case 1: m = 2. In this case k ≤ 2 and r ≤ 3.
+(1a): k = 1. We see that r = 2s. Thus (r, s) = (2, 1), contradicting Lemma 4.2(v).
+(1b): k = 2. We see that 2s = 3r. Thus (r, s) = (2, 3) and Lemma 4.2(v) shows that h0(A) = 0.
+This contradicts [A, Lemma 2] or [K, Thm. 5.1].
+
+8
+A.F. LOPEZ, D. RAYCHAUDHURY
+Case 2: m = 3. In this case k ≤ 3 and r ≤ 5.
+(2a): k = 1. We see that 4r = 15s. Thus, 15 divides r which is clearly impossible.
+(2b): k = 2. We see that 9s = 4r. Thus, 9 divides r which is a contradiction.
+(2c): k = 3. We see that 3s = 4r. Thus (r, s) = (3, 4) and Lemma 4.2(v) shows that h0(KX+8A) = 0.
+This is a contradiction by [GL, Thm. 1.2], as KX + 8A is base-point-free.
+Case 3: m = 4. In this case k ≤ 4 and r ≤ 7.
+(3a): k = 1. We see that 5r = 28s. Thus, 28 divides r which is clearly impossible.
+(3b): k = 2. We see that 4s = r. Thus (r, s) = (4, 1) and Lemma 4.2(v) shows h0(KX + 5A) =
+h0(H) = 0, a contradiction.
+(3c): k = 3. We see that 12s = 5r. Thus, 12 divides r which is absurd.
+(3d): k = 4. We see that 4s = 5r. Thus, (r, s) = (4, 5).
+We have KX = −4A and H = 5A. Hence H0(KX + 15A) = 0 by Lemma 4.2(v). Then
+PA(1) = PA(2) = PA(3) = PA(5) = PA(10) = PA(15) = 0,
+PA(0) = PA(4) = 1
+and
+PA(t) = A8
+8! (t − 1)(t − 2)(t − 3)(t − 5)(t − 10)(t − 15)(t2 + at + b).
+Therefore
+(4.8)
+1 = PA(0) = A8
+8! (4500b) =⇒ A8
+8! b =
+1
+4500
+and calculating the coefficient of t7 in (4.6) we get
+(4.9)
+A8
+8! (a − 36) = A7KX
+2(7!)
+=⇒ a = 20.
+We also know that PA(4) = 1 and that gives us
+−A8
+8! (396)(16 + 4a + b) = 1.
+We simplify the above using (4.8) and (4.9) to obtain
+−38016A8
+8! = 1 + 396
+4500
+which is clearly absurd.
+Case 4: m = 5. In this case k ≤ 5 and r ≤ 9.
+(4a): k = 1. We see that 2r = 15s. Thus, 15 divides r which is impossible.
+(4b): k = 2. We see that 35s = 6r. Thus, 35 divides r which is also impossible.
+(4c): k = 3. We see that 25s = 6r. Thus, 25 divides r which is also impossible.
+(4d): k = 4. We see that 5s = 2r. Thus (r, s) = (5, 2) and Lemma 4.2(v) shows that h0(KX +10A) =
+0. Then
+PA(1) = PA(2) = PA(3) = PA(4) = PA(6) = PA(8) = PA(10) = 0,
+PA(0) = PA(5) = 1
+so that we obtain
+PA(t) = A10
+10! (t − 1)(t − 2)(t − 3)(t − 4)(t − 6)(t − 8)(t − 10)(t3 + at2 + bt + c).
+Therefore
+(4.10)
+1 = PA(0) = −A10
+10! (11520c) = 1 =⇒ A10
+10! c = −
+1
+11520.
+and calculating the coefficient of t9 in (4.6) we get
+(4.11)
+A10
+10! (a − 34) = A9KX
+2(9!)
+=⇒ a = 9.
+We also know that PA(5) = 1 and that gives us
+−A10
+10! (360)(125 + 25a + 5b + c) = 1.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+9
+We simplify the above using (4.10) and (4.11) to obtain
+(4.12)
+A10
+10! b =
+1
+5(11520) −
+1
+5(360) − 70A10
+10! .
+Finally, calculating the coefficient of t8 in (4.6) we get
+(4.13)
+A10
+10! (b − 34a + 463) = A8(K2
+X + c2(X))
+12(8!)
+.
+We simplify (4.13) using (4.11) and (4.12) to obtain
+(4.14)
+67A10 + 5A8c2(X) + 1302 = 0.
+On the other hand, Lemma 4.3(vii) shows that
+115A10 = A8c2(X)
+and combining with (4.14), we get that A10 is negative, which is clearly impossible.
+(4e): k = 5. We see that 5s = 6r. Thus (r, s) = (5, 6). We have KX = −5A and H = 6A. Again
+H0(KX + 24A) = 0 by Lemma 4.2(v). Then
+PA(1) = PA(2) = PA(3) = PA(4) = PA(6) = PA(12) = PA(18) = PA(24) = 0,
+PA(0) = PA(5) = 1.
+Thus, we obtain
+PA(t) = A10
+10! (t − 1)(t − 2)(t − 3)(t − 4)(t − 6)(t − 12)(t − 18)(t − 24)(t2 + at + b).
+Then
+(4.15)
+1 = PA(0) = A10
+10! (746496b) =⇒ A10
+10! b =
+1
+746496.
+calculating the coefficient of t9 in (4.6) we get
+(4.16)
+A10
+10! (a − 70) = A9KX
+2(9!)
+=⇒ a = 45.
+We also know that PA(5) = 1 and that gives us
+A10
+10! (41496)(25 + 5a + b) = 1.
+We simplify the above using (4.15) and (4.16) to obtain
+A10 =
+�705000
+746496
+�
+(10!)
+which is clearly absurd since A10 is an integer.
+□
+Corollary 4.11. Suppose that KX = eH, e ∈ Z (hence, in particular, if Pic(X) = ZH). Then TX(k)
+is Ulrich if and only if (X, H, k) = (P1, OP1(1), −2).
+Proof. This follows by [Lop, Prop. 4.1(i)]. We give another proof. We have that e = n(2k−n−1)
+n+2
+by
+Lemma 4.3(ii). If k ≤ n+1
+2
+it follows by Theorem 4.10 that (X, H, k) = (P1, OP1(1), −2). Now assume
+that k > n+1
+2 , so that e ≥ 1. If n ≥ 2, Lemma 4.2(v) gives that k ≥ n + e, hence k(n − 2) + n ≤ 0, a
+contradiction. Then n = 1 and e = 2(k−1)
+3
+. But 0 = H0(TX(k − 1)) = H0((k − 1 − e)H), hence e ≥ k,
+so that k ≤ −2, contradicting k > 1.
+□
+Corollary 4.12. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 2 with TX(k) is Ulrich.
+Suppose that there is an ample line bundle A on X such that KX = rA, H = sA for some r, s ∈ Z
+(hence, in particular, if Pic(X) ∼= Z). Let m(H, A) := min{m ≥ 0 : H0(mH + qA) ̸= 0 for all q ≥ 1}.
+Then:
+(i) m(H, A) > (n−2)k−2
+n+2
+and, if n ≥ 3, then k < (n+2)m(H,A)+2
+n−2
+.
+(ii) If A is effective, then n = 2.
+(iii) If m(H, A) ≤ n − 3, then n ≤ 11.
+
+10
+A.F. LOPEZ, D. RAYCHAUDHURY
+Proof. Observe first that, if n ≥ 3, then (n−2)k−2 ≥ k−2 ≥ 0: In fact if k ≤ 1 we have a contradiction
+by Theorem 4.10. Now Lemma 4.3(ii) implies that
+(4.17)
+r(n + 2) = n(2k − n − 1)s
+and Lemma 4.2(v) gives
+(4.18)
+0 = H0(KX + (n − k − 1)H) = H0((nk − 2k − 2)s
+n + 2
+A).
+To see (i), notice that it is obvious for n = 2, for m(H, A) ≥ 0 by definition. If n ≥ 3 we see by (4.18)
+that (nk−2k−2)s
+n+2
+∈ Z and we can write (nk−2k−2)s
+n+2
+= as+b for some a, b ∈ Z with a ≥ 0, 0 ≤ b < s. Since
+H0(aH + bA) = 0 by (4.18), we get that
+(n − 2)k − 2
+n + 2
+− 1 < a ≤ m(H, A) − 1
+giving (i). Now suppose that A is effective. If n ≥ 3 we know that (n − 2)k − 2 ≥ 0, contradicting
+(4.18). This proves (ii). To see (iii), notice that if n ≥ 12, then k ≥ n + 2 by Theorem 4.10(ii) and (iii).
+Hence (n−2)k−2
+n+2
+> n − 3 and (4.18) gives that
+0 = H0((nk − 2k − 2)s
+n + 2
+A) = H0((n − 3)H + qA)
+for some q ≥ 1, contradicting the hypothesis m(H, A) ≤ n − 3.
+□
+5. Curves
+Throughout this section we will have that X ⊆ PN is a smooth irreducible curve.
+It follows by Lemma 4.3(i) and Theorem 4.9 that if n = 1 and TX(k) is an Ulrich line bundle, then
+(X, H, k) = (P1, OP1(1), −2), (P1, OP1(3), 0) or k ≥ 2 and g ≥ 2.
+We will give below examples with k = 2, 3, essentially on any curve. Then we will give a sharp bound
+on k depending on the genus.
+The case k = 2 can be characterized. Note that g ≥ 3 when k = 2 by Lemma 4.3(i).
+Lemma 5.1. Let X ⊆ PN be a smooth irreducible curve. Then TX(2) is Ulrich if and only if there
+exists M ∈ Pic(X) such that Hi(M) = 0 for i ≥ 0 and H = KX + M is very ample. This occurs if and
+only if g ≥ 3.
+Proof. If TX(2) is Ulrich, set M = H −KX. Then Hi(M) = Hi(TX(1)) = 0 for i ≥ 0 and KX +M = H
+is very ample. Vice versa let M ∈ Pic(X) be such that Hi(M) = 0 for i ≥ 0 and H = KX + M is very
+ample. Then Hi(TX(1)) = Hi(M) = 0 for i ≥ 0, so that TX(2) is Ulrich.
+Suppose that g ≥ 3 and let M ∈ Pic(X) be such that Hi(M) = 0 for i ≥ 0.
+We claim that
+H := KX + M is very ample. In fact deg M = g − 1 by Riemann-Roch, hence deg H = 3g − 3. If g ≥ 4,
+then deg H ≥ 2g + 1, hence H is very ample. If g = 3 we have that deg H = 2g and, as is well known,
+H is very ample unless H = KX + P + Q for two points P, Q ∈ X. But then M = P + Q is effective,
+a contradiction. Instead, if g = 2 we have that deg(KX + M) = 3 > 2g − 2, hence h0(KX + M) = 2
+by Riemann-Roch.
+Let P + Q + R be an effective divisor linearly equivalent to KX + M.
+Then
+KX + M − P − Q ∼ R, hence h0(KX + M − P − Q) = 1 and therefore KX + M is not very ample.
+□
+Example 5.2. The case k = 3 occurs on any curve X with (necessarily) odd genus g ≥ 9. This was
+suggested to us by E. Sernesi, whom we thank.
+Proof. Let d = 3(g−1)
+2
+. We claim that a general H ∈ Picd(X) is very ample. In fact, first observe that
+H1(H) = 0, for otherwise KX − H ≥ 0. But KX − H is a general line bundle of degree g−1
+2
+≤ g − 1,
+hence h0(KX − H) = 0. Now, if H were not very ample, there will be two points p, q ∈ X such that
+h0(H − p − q) ≥ h0(H) − 1. But this can be rewritten, by Riemann-Roch, as h1(H − p − q) ≥ 1, that
+is KX − H + p + q ≥ 0. Hence there are some points p1, . . . , p g+3
+2
+∈ X such that
+KX − H + p + q ∼ p1 + . . . + p g+3
+2
+that is
+H ∼ KX − p1 − . . . − p g+3
+2
++ p + q.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+11
+This means that H is in the image of the morphism h : X
+g+7
+2
+→ Picd(X) sending (p1, . . . , p g+3
+2 , p, q) to
+KX − p1 − . . . − p g+3
+2
++ p + q. But dim Imh ≤ g+7
+2
+< g, contradicting that H is general. This proves
+that there is a non-empty open subset W of Picd(X) such that any H ∈ W is very ample.
+Consider the surjective morphism ψ : Picd(X) → Pic3g−3(X) given by ψ(L) = 2L and the isomor-
+phism ϕ : Pic3g−3(X) → Picg−1(X) given by ϕ(L) = L − KX. Let U be the non-empty open subset
+of Picg−1(X) such that Hi(M) = 0 for i ≥ 0 for any M ∈ U. Now let H ∈ ψ−1(ϕ−1(U)) ∩ V ∩ W.
+Then H is very ample and 2H = KX + M. In the embedding given by H we have that Hi(TX(2)) =
+Hi(−KX + 2H) = Hi(M) = 0 for i ≥ 0, hence TX(3) is Ulrich.
+□
+Remark 5.3. If k ≥ 1 and g − 1 is a prime number, then k ∈ {2, 4}.
+Proof. By Lemma 4.3(i) we get that (k − 1)d = 3(g − 1) and g ≥ 2, hence d ≥ 4. If 3 does not divide
+k − 1 we get that 3 divides d and (k − 1)d
+3 = g − 1, so that k = 2. If 3 divides k − 1 we get that
+k−1
+3 d = g − 1, so that k = 4.
+□
+Example 5.4. Every odd k ≥ 3 occurs.
+Proof. Let E be an elliptic curve, let D be a divisor of degree 3 on E and let S = E × P1 with two
+projections π1 : S → E, π2 : S → P1. Set C0 = π∗
+2(OP1(1)). Then H = C0 + π∗
+1D is very ample on S.
+Let M ∈ Pic0(E) be not 2-torsion and let B = k−1
+2 D + M. Again H1 := (k + 2)C0 + π∗
+1B is very ample
+on S. Set
+L = −KS + (k − 1)H = (k + 1)C0 + π∗
+1(2B − 2M)
+so that
+L − H1 = −C0 + π∗
+1(B − 2M)
+while
+L − 2H1 = −(k + 3)C0 + π∗
+1(−2M)
+and it is easily seen by the K¨unneth formula, that Hi(L − pH1) = 0 for i ≥ 0, 1 ≤ p ≤ 2. Hence, if
+X ∈ |H1| is a smooth irreducible curve, the exact sequence
+0 → L − 2H1 → L − H1 → TX(k − 1) → 0
+shows that Hi(TX(k − 1)) = 0 for i ≥ 0, that is TX(k) is an Ulrich line bundle.
+□
+We now give a bound for k.
+We first analyze a special case.
+We use the notation (a; b1, b2, b3, b4, b5, b6) ∈ Z7 for the divisor
+aε∗L − �6
+i=1 biEi on a smooth cubic W ⊂ P3, where ε : W → P2 is the blow up in six points, no three
+collinear and not on a conic, with exceptional divisors Ei and L is a line in P2.
+Lemma 5.5. Let X ⊂ P3 be a smooth irreducible curve of genus 3 and degree 6 lying on a smooth cubic
+W. Then TX(2) is Ulrich if and only if X is linearly equivalent to one of the following divisors on W:
+(5.1)
+(4; 1, 1, 1, 1, 1, 1), (5; 2, 2, 2, 1, 1, 1), (6; 3, 2, 2, 2, 2, 1), (7; 3, 3, 3, 2, 2, 2), (8; 3, 3, 3, 3, 3, 3).
+Proof. Let D = −KW .
+We have that D · X = 6 and X2 = 10.
+Thus Riemann-Roch gives that
+χ(2D − X) = 0. Further, D(2D − X) = 0, whence H0(2D − X) = 0, for otherwise X ∼ 2D and then
+X2 = 12, a contradiction. Also, D(−3D + X) = −3, whence H0(−3D + X) = 0, which, be Serre’s
+duality, is H2(2D − X) = 0. Thus, also H1(2D − X) = 0. Now the exact sequence
+0 → 2D − 2X → 2D − X → TX(1) → 0
+gives that
+h1(TX(1)) = h2(2D − 2X) = h0(3KW + 2X)
+by Serre’s duality. Since deg TX(1) = 2, we deduce by Riemann-Roch, that TX(2) is Ulrich if and only
+if H1(TX(1)) = 0, hence
+(5.2)
+TX(2) is Ulrich if and only if H0(3KW + 2X) = 0.
+Let (a; b1, · · · , b6) with b1 ≥ b2 ≥ · · · ≥ b6 ≥ 0 be the class of X. It follows from the assumption on
+degree and genus that (A.7) holds, whence X is as in (5.1) by Lemma A.2. Using (5.2), it remains to
+show that H0(3KW + 2X) = 0 in all of these cases.
+
+12
+A.F. LOPEZ, D. RAYCHAUDHURY
+In case (4; 1, 1, 1, 1, 1, 1), we have that 3KW + 2X = (−1; 1, 1, 1, 1, 1, 1) is clearly not effective.
+In case (5; 2, 2, 2, 1, 1, 1), we have that 3KW + 2X = (1; −1, −1, −1, 1, 1, 1). If it were effective, then
+so would be (1; 0, 0, 0, 1, 1, 1), a contradiction since no three blown-up points are collinear.
+In case (6; 3, 2, 2, 2, 2, 1), we have that 3KW + 2X = (3; 3, 1, 1, 1, 1, −1). Assume it is effective. In-
+tersecting with (1; 1, 1, 0, 0, 0, 0) we see that (2; 2, 0, 1, 1, 1, −1) must be effective. Intersecting the latter
+with (1; 1, 0, 1, 0, 0, 0) we conclude that (1; 1, 0, 0, 1, 1, −1) must be effective, hence also (1; 1, 0, 0, 1, 1, 0),
+a contradiction since no three blown-up points are collinear.
+In case (7; 3, 3, 3, 2, 2, 2), we have that 3KW + 2X = (5; 3, 3, 3, 1, 1, 1). Assume it is effective. In-
+tersecting with (1; 1, 1, 0, 0, 0, 0) we see that (4; 2, 2, 3, 1, 1, 1) must be effective. Intersecting the latter
+with (1; 1, 0, 1, 0, 0, 0) we conclude that (3; 1, 2, 2, 1, 1, 1) must be effective. Finally, intersecting with
+(1; 0, 1, 1, 0, 0, 0) we conclude that (2; 1, 1, 1, 1, 1, 1) must be effective, a contradiction since the blown-
+up points do not lie on a conic.
+In case (8; 3, 3, 3, 3, 3, 3), we have that 3KW +2X = (7; 3, 3, 3, 3, 3, 3). Observe that D(3KW +2X) = 3.
+Thus, if 3KW + 2X were effective, it would contain a divisor Γ that is either irreducible, or is a union
+of three lines, or is a union of a line and a conic. Now pa(Γ) = −3, hence Γ is not irreducible. On the
+other hand, since the first coefficient of a line in W is at most 2 and of a conic at most 3, we see that
+Γ, whose first coefficient is 7, is not a union of three lines nor of a line and a conic. This contradiction
+shows that 3KW + 2X is not effective.
+□
+Now we give the sharp bound.
+Proof of Theorem 1. First assume that g = 0. Then Lemma 4.3(i) gives that k ≤ 0, that is the required
+bound, and if equality holds, then Theorem 4.9 shows that X is a curve of type (1, 2) on a smooth
+quadric.
+Thus, by Lemma 4.3(i), we can now assume that g ≥ 2.
+Observe that h0(H) ≥ 4. In fact, the only possibility remaining is that h0(H) = 3. But then KX =
+(d−3)H, g =
+�d−1
+2
+�
+and k = 3(d−3)
+2
++1 by Lemma 4.3(i). Now 0 = H0(TX(k −1)) = H0((−d+2+k)H)
+and therefore −d + 2 + k ≤ −1, giving the contradiction d ≤ 1.
+Now, if X has general moduli, since it has a g3
+d, the Brill-Noether theorem implies that ρ(g, 3, d) ≥ 0,
+that is d ≥ 3g+12
+4
+. By Lemma 4.3(i) we get that 3(g−1)
+k−1
+≥ 3g+12
+4
+, that gives k ≤ 4. This proves the last
+assertion of the theorem.
+Turning to the first assertion, let X ⊆ PN be a smooth irreducible curve of genus g ≥ 2 such that
+TX(k) is an Ulrich line bundle and assume that
+k ≥
+√8g + 1 − 1
+2
+.
+Using Lemma 4.3(i), the above inequality can be rephrased as
+(5.3)
+g ≥ 2
+9d2 − d + 1.
+Consider a general projection X′ of X to P3. Note that X′ ∼= X, hence TX′(k) is Ulrich. We first observe
+that X′ cannot be a complete intersection (hence, in particular, X′ is nondegenerate), for otherwise
+TX′(k) = lH for some l ∈ Z. Now TX′(k), being Ulrich, is globally generated by Lemma 3.2(vi), hence
+l ≥ 0. Also 0 = H0(TX′(k − 1)) = H0((l − 1)H) and therefore l = 0. Hence Lemma 3.2(vii) gives that
+d = h0(TX′(k)) = 1, a contradiction.
+Using Lemma 4.3(i) and Castelnuovo’s bound, we get that either (d, g, k) = (6, 3, 2) or d ≥ 7.
+Suppose that d ≥ 7.
+We aim to show that X′ must lie on a smooth quadric.
+To this end, observe that (5.3) and Lemma 4.3(i) imply that
+(5.4)
+g >
+�
+1
+6d(d − 3) + 1
+if d ≡ 0 (mod 3)
+1
+6d(d − 3) + 1
+3
+if d ≡ 1, 2 (mod 3)
+unless d = 9 and g = 10. But in the latter case it is easy to show that if X′ does not lie on a quadric,
+then it is a complete intersection of two cubics, a contradiction. Therefore (5.4) and [Ha2, Thm. 3.2]
+give that X′ lies on a quadric Q. Moreover Q is smooth, for otherwise it must be a cone, d = 2b + 1 is
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+13
+odd and g = b2 − b by [Ha1, Ex. V.2.9]. But then Lemma 4.3(i) gives that 4(k − 1) = 6b − 9 −
+3
+2b+1,
+and therefore b = 1, a contradiction.
+Thus X′ is a curve of type (a, b) on Q, with 2 ≤ a ≤ b. In particular X′ is linearly normal, hence
+X = X′. In the exact sequence
+0 → OQ(k + 1 − 2a, k + 1 − 2b) → OQ(k + 1 − a, k + 1 − b) → TX(k − 1) → 0
+since H0(TX(k − 1)) = 0, we get that
+H0(OQ(k + 1 − 2a, k + 1 − 2b)) = H0(OQ(k + 1 − a, k + 1 − b))
+hence k + 1 − b ≤ −1, for otherwise k + 1 − a ≥ k + 1 − b ≥ 0, but then X is a base-component of
+|OQ(k + 1 − a, k + 1 − b)|, contradicting the fact that this linear system is base-point-free. Therefore
+b ≥ k + 2. Moreover Lemma 4.3(i) can be rewritten now as
+(a + b)(k − 1) = 3((a − 1)(b − 1) − 1)
+that is
+a =
+b(k + 2)
+3b − k − 2
+and it is readily seen that b ≥ k + 2 is equivalent to a ≤ k
+2 + 1. Therefore b ≥ 2a. But the maximum
+genus of a curve of type (a, b) with b ≥ 2a and degree d is attained when b = 2
+3d. Therefore
+g ≤ (1
+3d − 1)(2
+3d − 1) = 2
+9d2 − d + 1.
+This shows that the inequality in (5.3) cannot be strict, and therefore g ≤ 2
+9d2−d+1, which is equivalent
+to (1.1). Moreover, if equality holds in (1.1), then it holds in (5.3) and therefore X is a curve of type
+(a, b) with b = 2
+3d, hence b = 2a and 2a = b ≥ k + 2 ≥ 2a, so that k is even, a = k
+2 + 1 and b = k + 2.
+Next consider the only remaining case, (d, g, k) = (6, 3, 2).
+Again X′ is linearly normal, hence X = X′. Also we have equality in (5.3) and if X lies on a quadric,
+then it must be of type (2, 4) and we are done in this case. Suppose therefore that X does not lie on
+a quadric. Then it is easily seen that JX/P3(3) is 0-regular, hence globally generated, and we get that
+X is contained in a smooth cubic. Therefore X is one of the curves (5.1) by Lemma 5.5 and TX(2) is
+Ulrich.
+Finally, to show that the bound (1.1) is sharp for every even k ≥ 0, let X be a curve of type
+(k
+2 + 1, k + 2) on a smooth quadric Q ⊂ P3, so that k =
+√8g+1−1
+2
+. It remains to show that TX(k) is
+Ulrich. Set k = 2c. We have
+TX(k − 1) = −KX + (k − 1)H = OQ(c, −1)|X
+and the exact sequence
+0 → OQ(−1, −2c − 3) → OQ(c, −1) → OQ(c, −1)|X → 0
+shows that Hi(OQ(c, −1)|X) = 0 for i ≥ 0, since Hi(OQ(c, −1)) = Hi(OQ(−1, −2c − 3)) = 0 for i ≥ 0.
+Hence TX(k) is Ulrich.
+□
+6. Surfaces
+Throughout this section we will have that X ⊆ PN is a smooth irreducible surface.
+We start by a characterization.
+Lemma 6.1. Let X ⊆ PN be a smooth irreducible surface. Then TX(k) is an Ulrich vector bundle if
+and only if
+(i) d = 4(g−1)
+2k−1
+(ii) HKX = (2k−3)d
+2
+.
+(iii) K2
+X = 5χ(OX) + (k−1)(k−2)d
+2
+.
+(iv) H0(TX(k − 1)) = 0.
+(v) H2(TX(k − 2)) = 0.
+Proof. Note that (i) and (ii) are equivalent, since HKX = 2(g − 1) − d. Now (ii) and (iii) are the
+conditions (2.2) in [C1, Prop. 2.1]. Hence the lemma follows by loc. cit.
+□
+
+14
+A.F. LOPEZ, D. RAYCHAUDHURY
+Now we show the possible cases.
+Proposition 6.2. Let X ⊆ PN be a smooth irreducible surface. If TX(k) is an Ulrich vector bundle,
+the following hold:
+(i) 0 ≤ k ≤ 3.
+Moreover, either
+(ii) k = 0 and (X, H) = (P2, OP2(2)), or
+(iii) k = 1 and X is a Del Pezzo surface of degree 5, or
+(iv) k = 2, q = 0 and X is a minimal surface of general type, or
+(v) k = 3, X is a minimal surface of general type with 2KX ≡ 3H, K2
+X = 9d
+4 , χ(OX) = d
+4. Moreover
+X is a ball quotient.
+Proof. We have that k ≥ 0 by Lemma 4.2(i).
+Now H1(TX) = 0 by Lemma 4.2(iv), that is X is
+infinitesimally rigid and [BC, Thm. 1.3] implies that either X is a minimal surface of general type or
+X is a Del Pezzo surface of degree j ≥ 5. In the latter case we have that HKX < 0 hence either k = 0
+and we get (ii) by Theorem 4.9, or k = 1 and K2
+X = 5 by Lemma 6.1(ii),(iii). This gives (iii). On the
+other hand, if X is a minimal surface of general type then HKX > 0, hence k ≥ 2 by Lemma 6.1(ii).
+Next, the Hodge index theorem H2K2
+X ≤ (HKX)2 can be rewritten, using Lemma 6.1(ii),(iii) as
+χ(OX) ≤ (2k2 − 6k + 5)d
+20
+.
+Similarly, the Bogomolov-Miyaoka-Yau inequality K2
+X ≤ 9χ(OX) can be rewritten as
+χ(OX) ≥ (k2 − 3k + 2)d
+8
+.
+Combining we get that
+(k2 − 3k + 2)d
+8
+≤ (2k2 − 6k + 5)d
+20
+and this gives that k ≤ 3 and moreover that, if k = 3, then equality holds in both inequalities. Hence,
+when k = 3 we have, as is well known, that X is a ball quotient and that H2KX ≡ (HKX)H, that is
+2KX ≡ 3H. Then K2
+X = 9d
+4 and χ(OX) = d
+4. Thus (i) and (v) are proved. Alternatively (i) follows
+by Theorem 2. To see (iv) observe that since k = 2 we have by the above that X is a minimal surface
+of general type. Now if pg = 0 then q = 0 by [Be2, Lemma VI.1 and Prop. X.1]. If pg ̸= 0 we have
+an inclusion H0(Ω1
+X) ⊆ H0(Ω1
+X(KX)) hence q = h0(Ω1
+X) ≤ h0(Ω1
+X(KX)) = h2(TX) = 0 since TX(2) is
+Ulrich. This proves (iv).
+□
+We now characterize the case k = 1 for surfaces.
+Theorem 6.3. Let X ⊆ PN be a smooth irreducible surface. Then TX(1) is an Ulrich vector bundle if
+and only if X is a Del Pezzo surface of degree 5 and H = −2KX. Moreover in the latter case TX(1) is
+very ample.
+Proof. If TX(1) is an Ulrich vector bundle, then Proposition 6.2 implies that X is a Del Pezzo surface
+of degree 5 and H2 + 2HKX = 0. Let ε : X → P2 be the blow-up map, with exceptional divisors Ei
+over the points Pi ∈ P2, 1 ≤ i ≤ 4 and let L be a line in P2. Then we can write
+H ∼ aε∗L −
+4
+�
+i=1
+biEi
+and, as H is very ample, we have, without loss of generality,
+b1 ≥ b2 ≥ b3 ≥ b4 ≥ 1, a ≥ b1 + b2 + 1
+and H2 + 2HKX = 0 is
+a2 − 6a + 4 =
+4
+�
+i=1
+(bi − 1)2.
+Setting ci = bi − 1, we get by Lemma A.1 the following possibilities:
+(a; b1, b2, b3, b4) ∈ {(6; 3, 1, 1, 1), (6; 2, 2, 2, 2), (7; 4, 2, 2, 1), (9; 4, 4, 4, 3)}.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+15
+In the case (6; 2, 2, 2, 2) we have that H = −2KX. We now exclude the other cases.
+Let H = 6ε∗L − 3E1 − E2 − E3 − E4. We will prove that h2(TX(−1)) = h0(Ω1
+X(H + KX)) ̸= 0, so
+that TX(1) cannot be an Ulrich vector bundle. To this end observe that, since ε∗Ω1
+P2 ⊂ Ω1
+X, we will be
+done in this case if we prove that
+H0(ε∗Ω1
+P2(H + KX)) ̸= 0.
+Now H + KX = 3ε∗L − 2E1, hence
+H0(ε∗Ω1
+P2(H + KX)) ∼= H0(IZ ⊗ Ω1
+P2(3))
+where Z ⊂ P2 is the 0-dimensional subscheme of length 2 supported on P1. Finally
+h0(IZ ⊗ Ω1
+P2(3)) ≥ h0(Ω1
+P2(3)) − 6 = 2 > 0
+and we are done in this case.
+Consider now the exact sequences, for any 1 ≤ i ≤ 4,
+0 → OEi(−Ei) → Ω1
+X|Ei → Ω1
+Ei → 0
+that is
+0 → OP1(1) → Ω1
+X|Ei → OP1(−2) → 0
+from which we get, for any 1 ≤ i ≤ 4, that
+(6.1)
+h1(Ω1
+X|Ei) = 1
+and
+(6.2)
+H1(Ω1
+X |Ei ⊗ OP1(2)) = 0.
+In the two remaining cases we will prove that h1(TX(−1)) = h1(Ω1
+X(H + KX)) ̸= 0.
+Let H = 7ε∗L − 4E1 − 2E2 − 2E3 − E4.
+Note that H + KX − E4 + E1 = 4ε∗L − 2E1 − E2 − E3 − E4 is very ample by [DR, Cor. 4.6], hence
+H2(Ω1
+X(H + KX − E4 + E1)) = 0
+by Bott vanishing [T, Thm. 2.1]. Then the exact sequence
+0 → Ω1
+X(H + KX − E4) → Ω1
+X(H + KX − E4 + E1) → Ω1
+X|E1(H + KX − E4 + E1) → 0
+and (6.2) imply that H2(Ω1
+X(H + KX − E4)) = 0. Now the exact sequence
+0 → Ω1
+X(H + KX − E4) → Ω1
+X(H + KX) → Ω1
+X|E4(H + KX) → 0
+and (6.1) imply that
+h1(Ω1
+X(H + KX)) ≥ h1(Ω1
+X |E4(H + KX)) = h1(Ω1
+X|E4) = 1.
+Let H = 9ε∗L − 4E1 − 4E2 − 4E3 − 3E4.
+Let C ∈ |ε∗L − E2 − E3| be the strict transform of a line through P2 and P3. Note that H + KX −
+C + E1 = 5ε∗L − 2E1 − 2E2 − 2E3 − 2E4 is very ample by [DR, Cor. 4.6], hence
+H2(Ω1
+X(H + KX − C + E1)) = 0
+by Bott vanishing [T, Thm. 2.1]. Then the exact sequence
+0 → Ω1
+X(H + KX − C) → Ω1
+X(H + KX − C + E1) → Ω1
+X|E1(H + KX − C + E1) → 0
+and (6.2) imply that H2(Ω1
+X(H + KX − C)) = 0. Now the exact sequence
+0 → OC(−C) → Ω1
+X|C → Ω1
+C → 0
+that is
+0 → OP1(1) → Ω1
+X|C → OP1(−2) → 0
+gives that h1(Ω1
+X |C) = 1. Finally, from the exact sequence
+0 → Ω1
+X(H + KX − C) → Ω1
+X(H + KX) → Ω1
+X|C(H + KX) → 0
+using that (H + KX)C = 0, we get that
+h1(Ω1
+X(H + KX)) ≥ h1(Ω1
+X|C(H + KX)) = h1(Ω1
+X|C) = 1.
+
+16
+A.F. LOPEZ, D. RAYCHAUDHURY
+This completes the proof under the assumption that TX(1) is an Ulrich vector bundle.
+Suppose now that X is a Del Pezzo surface of degree 5 and H = −2KX. Setting k = 1 in Lemma
+6.1, we have that d = 4(g − 1) and, in order to verify that TX(1) is an Ulrich vector bundle, we need to
+check that H0(TX) = H2(TX(−1)) = 0. The first vanishing is well known. As for the second, we first
+observe that for i < 2 we have
+hi(TX(−1)) = h2−i(Ω1
+X(H + KX)) = h2−i(Ω1
+X(−KX)) = 0
+by Bott vanishing [T, Thm. 2.1]. Therefore h2(TX(−1)) = χ(TX(−1)) = d − 4(g − 1) = 0. Finally, as
+X does not contain lines in the embedding given by H = −2KX, we have that TX(1) is very ample by
+[LS, Thm. 1]
+□
+7. Properties of complete intersections
+We collect some properties inherited by the complete intersections Xi of X (as in Notation 2.1),
+when TX(k) is an Ulrich vector bundle.
+Lemma 7.1. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Then q(X) = q(Xi) for
+2 ≤ i ≤ n.
+Proof. By Kodaira vanishing we have that H1(OXi+1(−1)) = H2(OXi+1(−1)) = 0 as long as 2 ≤ i ≤
+n − 1. Then the exact sequences
+0 → OXi+1(−1) → OXi+1 → OXi → 0
+imply that h1(OXi+1) = h1(OXi) for every 2 ≤ i ≤ n − 1, hence q(X) = q(Xi) for 2 ≤ i ≤ n.
+□
+Lemma 7.2. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Suppose that k ≤ n − 2
+and that TX(k) is Ulrich. Then Hi(OXi) = 0 for all i such that max{1, k + 1} ≤ i ≤ n − 1.
+Proof. Assume that max{1, k + 1} ≤ i ≤ n − 1. Since TX|Xi(k) is Ulrich, it follows by Lemma 3.2(iv)
+that Hi(TX |Xi(k + m)) = 0 for all m ≥ −i, hence Hi(TX |Xi(−1)) = 0. Now the exact sequence
+0 → TXi(−1) → TX|Xi(−1) → O⊕(n−i)
+Xi
+→ 0
+implies that Hi(OXi) = 0.
+□
+Lemma 7.3. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Suppose that k ≤ n − 1
+and that TX(k) is Ulrich. Assume that Hi(OX) = 0 for all i ≥ 1. Then Hi(OXj) = 0 for all i ≥ 1 and
+for all j such that max{1, k + 1} ≤ j ≤ n.
+Proof. Assume that i ≥ 1 and max{1, k + 1} ≤ j ≤ n. We prove the lemma by induction on n − j ≥ 0.
+If n − j = 0 then Xj = Xn = X and Hi(OX) = 0 for all i ≥ 1 just by our assumption.
+Next suppose that n − j ≥ 1, so that max{1, k + 1} ≤ j ≤ n − 1, hence, in particular k ≤ n − 2.
+Consider the exact sequence
+0 → OXj+1(−1) → OXj+1 → OXj → 0.
+If j = i, we have that Hj(OXj) = 0 by Lemma 7.2. Also, we have by induction that Hi(OXj+1) = 0.
+Now Hi+1(OXj+1(−1)) = 0 by Kodaira vanishing if i+1 < j+1 and by dimension reasons if i+1 > j+1.
+Thus Hi(OXj) = 0 if i ̸= j and we are done.
+□
+We now collect some properties of the Xi’s that hold when TX(1) is Ulrich.
+Lemma 7.4. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Suppose that n ≥ 2 and
+that TX(1) is an Ulrich vector bundle. Then:
+(i) H1(OXi) = 0 for 2 ≤ i ≤ n.
+(ii) H2(OXi) = 0 for 1 ≤ i ≤ n.
+(iii) H1(OXi(1)) = 0 for 1 ≤ i ≤ n.
+(iv) H2(OXi(1)) = 0 for 1 ≤ i ≤ n.
+(v) h0(OXi(1)) = d − g + i for 1 ≤ i ≤ n.
+(vi) d ≥ n + 3.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+17
+Proof. We have Hi(OX) = 0 for i ≥ 1 by Lemma 4.3(iii). Now (i) follows by Lemma 7.1 and (ii) follows
+by Lemma 7.3. To see (iii) observe that, if i = 1 we have that X1 = C and TX(1)|C is an Ulrich vector
+bundle on C by Lemma 3.2(ix), hence H1(TX |C) = 0. Then the exact sequence
+0 → TC → TX|C → OC(1)⊕(n−1) → 0
+shows that H1(OC(1)) = 0. If i ≥ 2, since H1(OXi) = 0 by (i), the exact sequences
+(7.1)
+0 → OXi → OXi(1) → OXi−1(1) → 0
+imply by induction that H1(OXi(1)) = 0 and we get (iii). Now (iv) is obvious for i = 1, while, for
+i ≥ 2, the exact sequences (7.1) and (ii) show by induction that H2(OXi(1)) = 0. This proves (iv).
+Note that (v) follows for i = 1 by Riemann-Roch and (iii). For i ≥ 2, the exact sequences (7.1) and
+(i) show by induction that h0(OXi(1)) = 1 + h0(OXi−1(1)) = d − g + i, that is (v). Finally, to see (vi),
+observe that g − 1 = n−1
+n+2d by Lemma 4.3(i), hence g ≥ 2 and (v) gives that
+3d
+n+2 = h0(OC(1)) ≥ 3, so
+that d ≥ n + 2. Moreover, if equality holds, we get that g = n and h0(OX(1)) = n + 2 by (v), hence
+X ⊂ PH0(H) = Pn+1 is a hypersurface of degree n + 2, so that KX = 0, contradicting Lemma 4.3(ii).
+Hence (vi) is proved.
+□
+8. TX(k) Ulrich and special varieties in adjunction theory
+In this section we exclude some special varieties frequently arising in adjunction theory, under the
+hypothesis that TX(k) is an Ulrich vector bundle. The cases (X, H) = (Pn, OPn(1)), (Qn, OQn(1)) have
+been already treated in Lemmas 4.1 and 4.5.
+We start by recalling the following (see [BS, I]).
+Definition 8.1. Let E be an effective divisor on (X, H). The divisor E is called exceptional
+(i) of type 1 if (E, H|E) ∼= (Pn−1, OPn−1(1)) and NE/X ∼= OPn−1(−1),
+(ii) of type 2 if (E, H|E) ∼= (Pn−1, OPn−1(1)) and NE/X ∼= OPn−1(−2),
+(iii) of type 3 if (E, H|E) ∼= (Qn−1, OQn−1(1)) and NE/X ∼= OQn−1(−1),
+(iv) of type 4 if (E, H|E) is a linear Pn−2-bundle over a smooth curve B and (NE/X)|F ∼= OPn−2(−1),
+where F is a fiber of the structure morphism E → B.
+Often these exceptional divisors will not be present under the condition that TX(k) is Ulrich. To see
+this we first prove
+Lemma 8.2. Let W be a variety of dimension s ≥ 1 and let OW (1) be a very ample line bundle. Then
+Ω1
+W(1) is not globally generated if:
+(i) (W, OW (1)) ∼= (Ps, OPs(1)).
+(ii) (W, OW (1)) is a (possibly singular) quadric hypersurface in Ps+1 and s ≥ 2.
+(iii) (W, OW (1)) is a smooth Del Pezzo variety, s ≥ 2 and (W, OW (1)) ̸∈ {(P2, OP2(3)), (Q2, OQ2(2)),
+(P3, OP3(2))}.
+Proof. (i) follows from det(Ω1
+Ps(1)) = OPs(−1). To see (ii), observe that the restricted Euler sequence
+0 → Ω1
+Ps+1|W (1) → H0(OW (1)) ⊗ OW → OW (1) → 0
+implies that H0(Ω1
+Ps+1|W(1)) = 0. Now the exact sequence
+0 → OPs+1(−3) → OPs+1(−1) → OW (−1) → 0
+implies that H1(OW (−1)) = 0 and the dual normal bundle sequence
+0 → OW (−1) → Ω1
+Ps+1|W(1) → Ω1
+W(1) → 0
+gives that H0(Ω1
+W (1)) = 0, hence Ω1
+W(1) is not globally generated. Next, to see (iii), observe that,
+from the classification of Del Pezzo varieties [IP, Thm. 3.3.1] it follows, for the surface section W2, that
+(W2, OW2(1)) ̸∈ {(P2, OP2(3)), (Q2, OQ2(2)). Hence, as is well known, W2, and hence W, contains a line
+L. But now the surjection Ω1
+W(1) → Ω1
+L(1) = OP1(−1) gives that Ω1
+W(1) is not globally generated.
+□
+Now
+
+18
+A.F. LOPEZ, D. RAYCHAUDHURY
+Lemma 8.3. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Assume that TX(k) is
+an Ulrich vector bundle. We have:
+(i) If k ≥ 1 and n ≥ 2, then (X, H) does not contain any exceptional divisor of type 1.
+(ii) If k ≥ 2 and n ≥ 2, then (X, H) does not contain any exceptional divisor of type 2.
+(iii) If k ≥ 2 and n ≥ 3, then (X, H) does not contain any exceptional divisors of types 3 or 4.
+Proof. Let E be an exceptional divisor. It follows from Lemma 4.6 that Ω1
+E(KX |E + (n + 1 − k)H|E) is
+globally generated. Now
+Ω1
+E(KX |E + (n + 1 − k)H|E) ∼=
+
+
+
+
+
+Ω1
+Pn−1(2 − k)
+if E is of type 1;
+Ω1
+Pn−1(3 − k)
+if E is of type 2;
+Ω1
+Qn−1(3 − k)
+if E is of type 3.
+Further, when E is of type 4, let F be a fiber of the structure morphism of E. Again it follows from
+Lemma 4.6 that Ω1
+F (KX |F + (n + 1 − k)H|F ) ∼= Ω1
+Pn−2(3 − k) is globally generated. Consequently, we
+draw the conclusions from Lemma 8.2.
+□
+We now recall
+Definition 8.4. We say that (X, H) is a linear Pk-bundle over a smooth variety B if (X, H) ∼=
+(P(F), OP(F)(1)), where F is a very ample vector bundle on B of rank k + 1.
+We say that (X, H) as above is a scroll (respectively a quadric fibration; respectively a Del Pezzo
+fibration) over a normal variety Y of dimension m if there exists a surjective morphism with connected
+fibers φ : X → Y such that KX +(n−m+1)H = φ∗L (respectively KX +(n−m)H = φ∗L; respectively
+KX + (n − m − 1)H = φ∗L), with L ample on Y .
+We now use the fibration to exclude several varieties as above, when TX(k) is an Ulrich vector bundle.
+Lemma 8.5. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1. Assume that TX(k) is
+an Ulrich vector bundle. Let f : X → B be a fibration onto a normal variety B of dimension m ≥ 1,
+with general fiber F. Then:
+(i) If m ≤ min{n − 1, k + 1}, then (F, H|F ) ̸= (Pn−m, OPn−m(1)).
+(ii) If m ≤ min{n − 2, k}, then (F, H|F) ̸= (Qn−m, OQn−m(1)).
+(iii) if m ≤ min{n − 2, k − 1}, then (F, H|F) is not a Del Pezzo variety, unless (F, H|F) ∈
+{(P2, OP2(3)), (Q2, OQ2(2)), (P3, OP3(2))}.
+Proof. We have that
+Ω1
+F(KF + (n + 1 − k)H|F) ∼=
+
+
+
+
+
+Ω1
+Pn−m(m − k)
+if (F, H|F) = (Pn−m, OPn−m(1));
+Ω1
+Qn−m(m − k + 1)
+if (F, H|F) = (Qn−m, OQn−m(1));
+Ω1
+F(m − k + 2)
+if (F, H|F) is a Del Pezzo variety.
+Now Ω1
+F(KF + (n + 1 − k)H|F ) is globally generated by Lemma 4.6. Hence, Lemma 8.2 gives that, in
+each of the three cases, the inequality in m, n, k is not satisfied.
+□
+We get a very useful consequence.
+Lemma 8.6. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 2. If TX(k) is an Ulrich
+vector bundle, then KX +(n−1)H is nef and H0(KX +(n−1)H) ̸= 0, unless (X, H, k) = (P2, OP2(2), 0)
+(the latter case actually occurs, see Theorem 4.9).
+Proof. Recall that H0(KX + (n − 1)H) ̸= 0 if and only if KX + (n − 1)H is nef by [BS, Cor. 7.2.8].
+Now if KX + (n − 1)H is not nef, it follows by [BS, Prop.’s 7.2.2, 7.2.3 and 7.2.4] that (X, H) is either
+(Pn, OPn(1)), (Qn, OQn(1)), a linear Pn−1-bundle over a smooth curve or (P2, OP2(2)). The first three
+cases are excluded by Lemmas 4.1, 4.5 and 8.5(i), while in the fourth case we have g = 0, hence k = 0
+by Lemma 4.3(i).
+□
+We can now prove Theorem 4.9.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+19
+Proof of Theorem 4.9. The assert is clear if either (X, H) = (P1, OP1(3)) or (P2, OP2(2)). Vice versa
+assume that TX is Ulrich for H. If n = 1, since TX = −KX is globally generated by Lemma 3.2(vi),
+we have that X is either P1 or an elliptic curve. Now the latter is excluded by Lemma 4.3(i), while in
+the former case TX = OP1(2) Ulrich implies that H = OP1(3). Now assume that n ≥ 2. Then Lemma
+8.6 gives that either (X, H) = (P2, OP2(2)), or KX + (n − 1)H is nef, leading, by Lemma 4.3(ii), to the
+contradiction
+0 ≤ (KX + (n − 1)H)Hn−1 = − 2d
+n + 2.
+□
+The following result will also be useful.
+Lemma 8.7. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 2. Suppose that k ≥ 1 and
+that TX(k) is an Ulrich vector bundle. Assume that X ∼= P(F) is a projective bundle over a normal
+projective variety B of dimension 1 ≤ m ≤ n − 1. Then B is smooth and F is simple. In particular, if
+m = 1, then q(X) ̸= 0.
+Proof. Let π : X ∼= P(F) → B be the structure morphism and let ξ be the tautological bundle of
+P(F). By twisting F with a sufficiently ample line bundle we can assume that ξ is ample. Then [BS,
+Prop. 3.2.1] implies that B is smooth. Since H0(TX) = 0, the cohomology of the exact sequence
+0 → TX/B → TX → π∗TB → 0
+gives that H0(TX/B) = 0. Now the cohomology of the exact sequence
+0 → OX → π∗F∗ ⊗ ξ → TX/B → 0
+implies that
+h0(F ⊗ F∗) = h0(π∗F∗ ⊗ ξ) = h0(OX) = 1.
+Now if m = 1 and q(X) = 0 we have that B ∼= P1, hence F cannot be simple since rk F = n ≥ 2.
+□
+Next we prove three results for k = 2.
+For the first one, in order to apply the results of T. Fujita in [F1], we give the following definition,
+that coincides with the one in [F1] when B is smooth.
+Definition 8.8. Let f : X → B be a fibration over a curve, L an ample line bundle on X such that on
+the general fiber F we have that KF = −(n − 2)L|F . We say that f is minimal if there is a line bundle
+L on B such that KX + (n − 2)L = f ∗L.
+Then we have
+Lemma 8.9. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 4. Suppose that k ≥ 2 and
+that k = 2 if n = 4. Moreover assume that TX(k) is an Ulrich vector bundle. Then:
+(i) (X, H) is not a Del Pezzo fibration over a smooth curve.
+(ii) If n = 4 and KX + 2H is ample, then (X, KX + 2H) is not a minimal (P3, OP3(2))-fibration
+over a smooth curve.
+Proof. For the sake of contradiction, let L be H in case (i) and KX + 2H in case (ii). Assume that we
+have a fibration f : X → B over a smooth curve B such that (X, L) is a Del Pezzo fibration in case (i)
+(see Definition 8.4) and (X, L) is a minimal (P3, OP3(2))-fibration in case (ii). Note that f is minimal
+also in case (i) by Definition 8.4.
+Let F be a general fiber of f. In case (i) we have that F is a smooth variety of dimension n − 1 and
+KF = KX|F = −(n − 2)L|F, hence F is a Del Pezzo variety. Since L = H, Lemma 8.5 implies that
+(F, H|F) = (P3, OP3(2)), hence n = 4. Thus (F, L|F ) is the same in both cases.
+We now claim that every fiber of f is irreducible. Indeed, if not, let F0 be a reducible fiber. Since
+F0 is connected, it must be singular, hence we can apply [F1, Table (2.20)]. It follows that we are in
+case (2.17) of [F1, Table (2.20)], the degree of F0 is 8 and, if D is an irreducible component of F0, then
+(D, L|D) is a scroll over P1 and KX |D = −2L|D. Denoting a fiber of the structure morphism D → P1
+by F ′ ∼= P2, we obtain L|F ′ = OP2(1) and KX|F ′ = −2L|F ′ = OP2(−2). Set H|F ′ = OP2(a). In case (ii)
+we have that
+OP2(1) = L|F ′ = (KX + 2H)|F ′ = OP2(−2 + 2a)
+
+20
+A.F. LOPEZ, D. RAYCHAUDHURY
+a contradiction. In case (i) we have that L = H and a = 1. But now Lemma 4.6 gives that Ω1
+P2(KX |F ′ +
+3H|F ′) ∼= Ω1
+P2(1) is globally generated, contradicting Lemma 8.2(i). Thus every fiber of f is irreducible.
+Now [F1, (4.8)] implies that every fiber of f is P3. Since B is a smooth curve, it follows, as is well
+known, that X is a projective bundle over B. On the other hand, since n = 4, we have that k = 2 and
+q(X) = 0 by Lemma 4.3(iii), contradicting Lemma 8.7.
+□
+Lemma 8.10. Let X ⊆ PN be a smooth irreducible variety of dimension 4. Suppose that KX + 2H is
+ample and that TX(2) is an Ulrich vector bundle. Then (X, KX + 2H) is not a quadric fibration over
+a smooth curve.
+Proof. Suppose that (X, KX + 2H) is a quadric fibration π : X → B over a smooth curve. Since
+χ(OX) = 1 by Lemma 4.3(iii), it follows from [Lan, Sect. 1.1, eq. (8)] that B ∼= P1. Moreover, [Lan,
+Sect. 0.1] gives that if π∗(KX + 2H) ∼=
+4�
+i=0
+OP1(ai) and e = �4
+i=0 ai, then there is b ∈ Z such that
+(KX + 2H)4 = 2e − b
+by [Lan, Sect. 1.1, eq. (3)] and
+Ki
+X(KX + 2H)4−i = (−3)i2e + (−3)i−1(−4i + 2ie + (3 − 2i)b) for 1 ≤ i ≤ 4
+by [Lan, Sect. 1.1, eq. (4)]. Solving these five equations we obtain
+KXH3 = 4e − 28b − 104 and d = H4 = 16b + 64
+and therefore Lemma 4.3(iii) gives
+(8.1)
+13d = 48(2 + e).
+Since TX(2) is Ulrich we have that H4(TX(−2)) = 0 and the exact sequence
+0 → TX/P1(−2) → TX(−2) → (π∗TP1)(−2) → 0
+implies that H4((π∗TP1)(−2)) = 0. Hence, by Serre duality
+0 = h4((π∗TP1)(−2)) = h0((π∗OP1(−2))(KX+2H)) = h0(π∗(KX+2H)⊗OP1(−2)) =
+4
+�
+i=0
+h0(OP1(ai−2))
+and therefore ai ≤ 1 for 0 ≤ i ≤ 4. But then e ≤ 5 and (8.1) gives that 1 ≤ e + 2 ≤ 7 is divisible by 13,
+a contradiction.
+□
+Lemma 8.11. Let X ⊆ PN be a smooth irreducible variety of dimension 4. Suppose that KX + 2H is
+ample and that TX(2) is an Ulrich vector bundle. Then (X, KX + 2H) is not a linear P2-bundle over
+a smooth surface.
+Proof. Assume by contradiction that we have a P2-bundle structure π : X ∼= P(F) → B onto a smooth
+surface B, with KX + 2H = ξ, the tautological bundle, where F is a rank 3 vector bundle on B. Then
+H = aξ − π∗M for some a ∈ Z and M ∈ Pic(B), so that
+ξ = KX + 2H = (2a − 3)ξ + π∗(KB + c1(F) − 2M)
+giving a = 2 and 2M = KB + c1(F), thus
+(8.2)
+H ≡ 2ξ − 1
+2π∗(KB + c1(F)).
+We will also use Grothendieck’s relation
+3�
+j=0
+(−1)jξ3−jπ∗cj(F) = 0, that is
+(8.3)
+ξ3 = ξ2π∗c1(F) − ξπ∗c2(F).
+Since ξ2f = 1 for every fiber f of π, we get from (8.3) that
+(8.4)
+ξ3π∗c1(F) = c1(F)2, ξ3π∗KB = KBc1(F) and ξ4 = c1(F)2 − c2(F).
+We first collect some invariants of X and B.
+Claim 8.12. We have:
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+21
+(i) KXH3 = − 2
+3d.
+(ii) χ(OX) = 1.
+(iii) χ(OX(H)) = 2 + χ(OS) − d
+6.
+(iv) h0(KX + 2H) = χ(OS) − 1.
+(v) χ(OB) = 1.
+Proof. (i) is obtained by Lemma 4.3(ii). Now Lemma 4.3(iii) gives that Hi(OX) = 0 for i ≥ 1, hence
+Hi(OB) = 0 for i ≥ 1, giving (ii) and (v). Next, to see (iii), consider the exact sequences
+0 → OXi → OXi(H) → OXi−1(H) → 0
+for i = 4, 3. They give χ(OX(H)) = 1+χ(OX3(H)) = 2+χ(OS(H)) and (iii) follows by Riemann-Roch
+since H2
+|S = d and H|SKS = (KX + 2H)H3 = 4
+3d by (i). To see (iv), observe that, since Rjπ∗(−ξ) = 0
+for every j ≥ 0, we have that Hi(KX + H) = Hi(−ξ + π∗(KB + c1(F) − M)) = 0 for every i. Hence
+the exact sequence
+0 → KX + H → KX + 2H → KX3 + H|X3 → 0
+implies that
+(8.5)
+h0(KX + 2H) = h0(KX3 + H|X3).
+Now we have q(S) = 0 by Lemma 7.1 and Hi(KX3) = 0 for i = 0, 1 by Serre duality and Lemma 7.3.
+Hence the exact sequence
+0 → KX3 → KX3 + H|X3 → KS → 0
+shows that
+χ(OS) − 1 = pg(S) = h0(KS) = h0(KX3 + H|X3)
+and we get (iv) by (8.5).
+□
+We continue the proof of the lemma.
+Next, we collect some relations among the invariants related to ξ, KB and the Chern classes of F.
+Claim 8.13. The following identities hold:
+(i) d − 6c1(F)2 + 16c2(F) − 6K2
+B + 4KBc1(F) = 0.
+(ii) KBc1(F) − 8 + 2χ(OS) − c1(F)2 + 2c2(F) = 0.
+(iii) K2
+B − 1 + c1(F)2 − 3c2(F) = 0.
+(iv) 3K2
+B + c1(F)2 − 2c2(F) − 30 = 0.
+(v) 4 − KBc1(F) + 9
+4K2
+B + 7
+4c1(F)2 − 5c2(F) − χ(OS) + 1
+6d = 0.
+Proof. We have by (8.2) and (8.4) that
+d = H4 = (2ξ − 1
+2π∗(KB + c1(F)))4 = 16(c1(F)2 − c2(F)) + 6K2
+B − 4KBc1(F) − 10c1(F)2
+that is (i). To see (ii) observe that, since π∗ξ = F and Rjπ∗ξ = 0 for j > 0 we have Hi(F) = Hi(ξ) =
+Hi(KX + 2H) = 0 for i > 0 by Kodaira vanishing. Also, by Claim 8.12(iv), (v) and Riemann-Roch we
+get
+χ(OS) − 1 = h0(KX + 2H) = h0(ξ) = h0(F) = χ(F) = 3 − 1
+2KBc1(F) + 1
+2c1(F)2 − c2(F)
+that is (ii). Next, consider the exact sequences
+(8.6)
+0 → TX/B → TX → π∗TB → 0
+and
+0 → OX → π∗F∗(ξ) → TX/B → 0.
+Since TX(2H) is Ulrich, we have that χ(TX) = 0, hence, using Claim 8.12(ii) we get
+(8.7)
+χ(TB) = χ(π∗TB) = −χ(TX/B) = −χ(π∗F∗(ξ)) + 1 = −χ(F ⊗ F∗) + 1.
+On the other hand, by Riemann-Roch and Claim 8.12(v), χ(TB) = 2K2
+B − 10 and χ(F ⊗ F∗) =
+9 + 2c1(F)2 − 6c2(F). Replacing in (8.7) gives (iii).
+
+22
+A.F. LOPEZ, D. RAYCHAUDHURY
+Finally, to see (iv), we first compute c1(S2(F)) = 4c1(F) and c2(S2(F)) = 5c1(F)2 + 5c2(F), so that
+c1(S2(F)(−M)) = −3KB + c1(F), c2(S2(F)(−M)) = 15
+4 K2
+B − 5
+2KBc1(F) − 5
+4c1(F)2 + 5c2(F).
+Now Riemann-Roch gives
+(8.8)
+χ(S2(F)(−M)) = 6 − KBc1(F) + 9
+4K2
+B + 7
+4c1(F)2 − 5c2(F).
+On the other hand, χ(S2(F)(−M)) = χ(2ξ − π∗M) = χ(OX(H)) = 2 + χ(OS) − d
+6 by Claim 8.12(iii).
+Using (8.8) we get (v).
+□
+We now conclude the proof of the lemma.
+Solving the five equations in Claim 8.13 we get
+(8.9)
+K2
+B = − 7
+48d + 7 and KBc1(F) = − 5
+48d + 9.
+In particular d ≥ 48. On the other hand, using Claim 8.12(i), we get
+µ(TX) = −KXH3
+4
+= 1
+6d
+and, using (8.2)
+µ(π∗TB) = c1(π∗TB)H3
+2
+= −π∗KB
+�
+2ξ − 1
+2π∗(KB + c1(F))
+�3
+2
+= −8ξ3π∗KB − 6ξ2π∗(K2
+B + KBc1(F))
+2
+.
+Now (8.4) and (8.9) give
+µ(π∗TB) = −KBc1(F) + 3K2
+B = −1
+3d + 12.
+Since TX is semistable by Lemma 4.3(v), we deduce by (8.6) that
+1
+6d ≤ −1
+3d + 12
+that is d ≤ 24, a contradiction.
+□
+9. TX(1) Ulrich in any dimension
+We study the case k = 1 in any dimension. We start analyzing the properties of the curve section C
+and of the surface section S.
+Lemma 9.1. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 3. If TX(1) is an Ulrich
+vector bundle, then d ≥ 9 except, possibly, when d = 8, g = 5, n = 4 and h0(OC(1)) = 4.
+Proof. By Lemma 4.3(i) we know that g ≥ 2 and that
+(9.1)
+(n − 1)d = (n + 2)(g − 1).
+By Lemma 7.4(v) we have d − g + 1 = h0(OC(1)) ≥ 3, hence g ≤ d − 2.
+Also, if equality holds,
+then h0(OC(1)) = 3, so that d − 2 = g =
+�d−1
+2
+�
+, thus d = 3 and g = 1, a contradiction. Therefore
+2 ≤ g ≤ d − 3, hence d ≥ 5. But if d ≤ 8 the only possibility given by (9.1) is d = 8, g = 5, n = 4 and
+h0(OC(1)) = 4.
+□
+Lemma 9.2. Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 3. If TX(1) is an Ulrich
+vector bundle we have:
+(i) KSH|S = n−4
+n+2d.
+(ii) q(S) = pg(S) = 0.
+(iii) K2
+S = − 3(n−2)
+2(n+2)d − n−12
+2
+.
+(iv) S is rational.
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+23
+Proof. (i) follows by Lemma 4.3(ii), while (ii) follows by Lemma 4.3(iii), Lemma 7.1 and Lemma 7.4(ii).
+Note now that the equation in Lemma 4.3(vii) can be rewritten as
+3(n − 2)d + 2(n + 2)K2
+S + (n + 2)(n − 12) = 0
+giving (iii).
+Finally assume that S is not ruled, so that κ(S) ≥ 0.
+Then Lemma 8.6 gives that
+KS + H|S = (KX + (n − 1)H)|S is nef, hence KS(KS + H|S) ≥ 0, that is K2
+S ≥ −KSH|S = − n−4
+n+2d by
+(i). Then (iii) gives
+−3(n − 2)
+2(n + 2)d − n − 12
+2
+= K2
+S ≥ −n − 4
+n + 2d
+so that
+(n + 2)(d + n − 12) ≤ 0.
+Since n ≥ 3 it follows that d ≤ 9, and using Lemma 9.1 we deduce that either d = 9, n = 3 or
+d = 8, g = 5, n = 4 and h0(OC(1)) = 4. In the first case we get a contraction by Lemma 4.3(i), while in
+the second case d + n − 12 = 0, hence K2
+S = 0. As C ⊂ P3 we deduce that S ⊂ P4. But this contradicts
+the well-known formula for the invariants of a surface in P4. Therefore S is ruled, hence rational by (ii)
+and (iv) is proved.
+□
+We are now ready to prove Theorem 3.
+Proof of Theorem 3. If n = 1 we know by Lemma 4.3(i) that TX(1) is not an Ulrich vector bundle. If
+n = 2 this is Theorem 6.3. Suppose next that n ≥ 3. Note that H0(TX) = 0 by Lemma 4.2(iii), hence
+X is neither Pn nor Qn. Also q(X) = 0 by Lemma 4.3(iii). We have that (X, H) is not:
+(1) A projective bundle over a smooth curve by Lemma 8.7.
+(2) A Del Pezzo manifold by Lemma 4.3(i), since otherwise g = 1.
+(3) A hyperquadric fibration over a smooth curve (in the sense of [I]), by Lemma 8.5(ii).
+(4) A linear Pn−2-bundle over a smooth surface, by Lemma 8.5(i).
+Also observe that X does not contain any exceptional divisor of type 1 by Lemma 8.3(i). Hence (X, H)
+is isomorphic to its reduction (X′, H′) (see [I, (0.11)]). It follows by [I, Thm. (1.7)] that KX +(n−2)H
+is nef. Hence S is minimal and rational by Lemma 9.2(iv), a contradiction since a minimal rational
+surface does not have nef canonical bundle. Thus the case n ≥ 3 does not occur and the theorem is
+proved.
+□
+10. TX(2) Ulrich in any dimension
+We prove Theorem 4.
+Proof Theorem 4. It follows by Lemma 4.2(iii) that H0(TX) = 0, hence X is neither Pn nor Qn. Note
+that Hi(OX) = 0 for i ≥ 1 by Lemma 4.3(iii) and KX is not nef, since Lemma 4.3(ii) gives that
+KXHn−1 = n(3−n)
+n+2 d < 0.
+We divide the proof according to the value of τ(X, H) (see (4.3)). We will also use the notions of
+first and second reduction of (X, H), as defined in [BS, Defs. 7.3.3 and 7.5.7].
+Case A: τ(X, H) ≥ n − 1.
+This case does not occur since Lemma 4.6(iii) implies that τ(X, H) ≤ n −
+2n
+n+1 < n − 1.
+Case B: n − 2 ≤ τ(X, H) < n − 1.
+Then KX +(n−1)H is ample, hence the first reduction exists and is isomorphic to (X, H). Therefore
+[BS, Thm. 7.3.4] implies that τ(X, H) = n − 2 and then [BS, Thm. 7.5.3] gives that (X, H) is one of
+the following:
+(B.1) a Mukai variety,
+(B.2) a Del Pezzo fibration over a smooth curve,
+(B.3) a quadric fibration over a normal surface,
+(B.4) a scroll over a normal threefold,
+(B.5) (X, H) contains an exceptional divisor of type 2, 3, or 4.
+
+24
+A.F. LOPEZ, D. RAYCHAUDHURY
+Now, the case (B.1) is ruled out by Corollary 4.11. Case (B.2) is excluded for n = 4 by Lemma 8.9(i)
+and for n ≥ 5 by Lemma 8.5(iii). Also the cases (B.3) and (B.4) are ruled out by Lemma 8.5(ii) and
+(i). Finally the case (B.5) is excluded by Lemma 8.3(ii) and (iii).
+Thus also Case B does not occur.
+Case C: τ(X, H) < n − 2.
+Then the first and second reductions exist and are both isomorphic to (X, H), since KX + (n − 2)H
+is ample.
+We first claim that KX3 is not nef. In fact, assume that KX3 is nef. On the one hand, χ(OX3) = 1
+by Lemma 7.3. On the other hand, 3c2(X3) − c1(X3)2 is pseff by [M, Thm. 1.1], hence 3c2(X3)KX3 ≥
+K3
+X3 ≥ 0. But then Riemann-Roch gives χ(OX3) = − 1
+24c2(X3)KX3 ≤ 0, a contradiction.
+Hence KX3 is not nef and [BS, Prop. 7.9.1] gives the following cases:
+(C.1) n = 5 and (X, KX + 3H) is a linear P4-bundle over a smooth curve.
+(C.2) n = 4 and (X, KX + 2H) is a Del Pezzo.
+(C.3) n = 4 and (X, KX + 2H) is a quadric fibration over a smooth curve.
+(C.4) n = 4 and (X, KX + 2H) is a scroll over a normal surface.
+(C.5) n = 4 and (X, H) contains an exceptional divisor of type 2.
+(C.6) n = 4 and (X, KX + 2H) is a (P3, OP3(2))-fibration over a curve.
+In case (C.1) we have a contradiction by Lemma 8.7. In case (C.2) we have 4KX + 6H = 0, hence
+4KXH3+6H4 = 0 and Lemma 4.3(ii) gives the contradiction d = 0. Cases (C.3) and (C.5) do not occur
+by Lemmas 8.10 and 8.3(ii). In Case (C.6) we observe that the fibration is obtained in [F2, (4.6.1)] by
+contracting an extremal ray, hence it is minimal (see Definition 8.8) and the image is a normal, hence
+smooth, curve. Thus this case is excluded by Lemma 8.9(ii).
+Hence we are left with case (C.4). We have a surjective morphism π : X → B and denoting by F a
+general fiber, we have (F, (KX + 2H)|F ) ∼= (P2, OP2(1)). Now all fibers of π are 2-dimensional by [BS,
+Thm. 14.1.1], hence we get by [BS, Prop. 3.2.1] that B is a smooth surface and (X, KX + 2H) is a
+linear P2-bundle over B. But this case is excluded by Lemma 8.11.
+This concludes the proof of the theorem.
+□
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+Publ. Math. Inst. Hautes ´Etudes Sci. 129 (2019), 1-49. 5
+[DR]
+S. Di Rocco. k-very ample line bundles on del Pezzo surfaces. Math. Nachr. 179 (1996), 47-56. 15
+[ES]
+D. Eisenbud, F.-O. Schreyer. Resultants and Chow forms via exterior syzygies. J. Amer. Math. Soc. 16 (2003),
+no. 3, 537-579. 1, 3
+[F1]
+T. Fujita. On del Pezzo fibrations over curves. Osaka J. Math. 27 (1990), no. 2, 229-245. 19, 20
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+25
+[F2]
+T. Fujita. On Kodaira energy and adjoint reduction of polarized manifolds. Manuscripta Math. 76 (1992), no.
+1, 59?84. 24
+[FL1]
+M. Fulger, B. Lehmann. Morphisms and faces of pseudo-effective cones. Proc. Lond. Math. Soc. 112 (2016),
+no. 4, 651-676. 5
+[FL2]
+M. Fulger, B. Lehmann. Positive cones of dual cycle classes. Algebr. Geom. 4 (2017), no. 1, 1-28. 5
+[GL]
+L. Ghidelli, J. Lacini. Logarithmic bounds on Fujita’s conjecture. Preprint 2021, arXiv:2107.11705. 8
+[Ha1]
+R. Hartshorne. Algebraic geometry. Graduate Texts in Mathematics 52. Springer-Verlag, New York-Heidelberg,
+1977. 13
+[Ha2]
+R. Hartshorne. On the classification of algebraic space curves. Vector bundles and differential equations (Proc.
+Conf., Nice, 1979), pp. 83-112, Progr. Math., 7, Birkh¨auser, Boston, Mass., 1980 12
+[Ho]
+A. H¨oring. On a conjecture of Beltrametti and Sommese. J. Algebraic Geom. 21 (2012), no. 4, 721-751. 7
+[I]
+P. Ionescu. Generalized adjunction and applications. Math. Proc. Cambridge Philos. Soc. 99 (1986), no. 3,
+457-472. 17, 23
+[IP]
+V. A. Iskovskikh, Yu. Prokhorov. Fano varieties. In: Algebraic geometry, V, 1-247, Encyclopaedia Math. Sci.
+47, Springer-Verlag, Berlin, 1999. 17
+[K]
+Y. Kawamata. On effective non-vanishing and base-point-freeness. Kodaira’s issue. Asian J. Math. 4 (2000),
+no. 1, 173-181. 7
+[Lan]
+A. Lanteri. Hilbert curves of quadric fibrations. Internat. J. Math. 29 (2018), no. 10, 1850067, 20 pp. 20
+[Lop]
+A. F. Lopez. On varieties with Ulrich twisted normal bundles. Preprint 2022, arXiv:2205:06602. 1, 9
+[Laz]
+R. Lazarsfeld. Positivity in algebraic geometry, I. Ergebnisse der Mathematik und ihrer Grenzgebiete, 3. Folge
+48, Springer-Verlag, Berlin, 2004. 3
+[LS]
+A. F. Lopez, J. C. Sierra. A geometrical view of Ulrich vector bundles. Preprint 2021, arXiv:2105.05979. To
+appear on Int. Math. Res. Not. IMRN. 5, 16
+[M]
+Y. Miyaoka. The Chern classes and Kodaira dimension of a minimal variety. In: Algebraic geometry, Sendai,
+1985, 449-476, Adv. Stud. Pure Math., 10, North-Holland, Amsterdam, 1987. 24
+[MS]
+S. Mori, H. Sumihiro. On Hartshorne’s conjecture. J. Math. Kyoto Univ. 18 (1978), no. 3, 523-533. 4
+[T]
+B. Totaro. Bott vanishing for algebraic surfaces. Trans. Amer. Math. Soc. 373 (2020), no. 5, 3609-3626. 15, 16
+[W]
+J. M. Wahl. A cohomological characterization of Pn. Invent. Math. 72 (1983), no. 2, 315-322. 4
+Appendix A. Some numerical lemmas
+Lemma A.1. Let (a; c1, c2, c3, c4) ∈ Z5 be such that c1 ≥ c2 ≥ c3 ≥ c4 ≥ 0, a ≥ c1 + c2 + 3 and
+(A.1)
+a2 − 6a + 4 = c2
+1 + c2
+2 + c2
+3 + c2
+4.
+Then (a; c1, c2, c3, c4) ∈ {(6; 2, 0, 0, 0), (6; 1, 1, 1, 1), (7; 3, 1, 1, 0), (9; 3, 3, 3, 2)}.
+Proof. We have
+(A.2)
+a − 3 ≥ c1 + c2.
+Now, (A.1) and (A.2) imply that (a − 3)2 − 5 = c2
+1 + c2
+2 + c2
+3 + c2
+4 ≥ (c1 + c2)2 − 5, that is
+(A.3)
+c2
+3 + c2
+4 ≥ 2c1c2 − 5.
+But 2c2
+3 ≥ c2
+3 + c2
+4 and 2c1c2 ≥ 2c2
+2. Consequently, we get
+(A.4)
+5 ≥ 2(c2 − c3)(c2 + c3).
+Thus, one of the following should happen:
+(α) c2 = c3.
+(β) c2 = c3 + 1.
+First assume that case (β) holds.
+Then (A.4) yields 2c3 ≤ 1 which gives c3 = 0, c2 = 2 and hence c4 = o. The (A.1) gives
+(a + c1 − 3)(a − c1 − 3) = 6.
+Thus we have one of the following possibilities
+a + c1 = 4, a − c1 = 9, or a + c1 = 5, a − c1 = 6, or a + c1 = 6, a − c1 = 5, or a + c1 = 9, a − c1 = 4
+but none of them have integer solutions.
+Assume now that case (α) holds.
+Set c2 = c3 = c. From (A.3), we obtain c2 + c2
+4 ≥ 2c1c − 5. Since c ≥ c4, we get
+(A.5)
+5 ≥ 2c(c1 − c).
+The above implies one of the following happens:
+
+26
+A.F. LOPEZ, D. RAYCHAUDHURY
+(α1) c2 = c3 = c4 = 0.
+(α2) c1 = c2 = c3.
+(α3) c2 = c3 = 1. This case has two sub-cases, namely c1 = 2, 3.
+(α4) c2 = c3 = 1, c1 = 3.
+Suppose we are in case (α1).
+Then (A.1) gives (a − 3)2 − 5 = c2
+1, so that (a + c1 − 3)(a − c1 − 3) = 5.
+In this case, either
+a + c1 = 4, a − c1 = 8, giving the contradiction c1 = −2, or a + c1 = 8, a − c1 = 4, giving a = 6, c1 = 2
+and the solution (6; 2, 0, 0, 0).
+Suppose we are in case (α2).
+Using (A.3) we conclude
+(A.6)
+5 ≥ (c − c4)(c + c4).
+As before, we obtain the following cases:
+(α21) c = c1 = c2 = c3 = c4.
+(α22) c = c4 + 1.
+(α23) c = c4 + 2.
+We first deal with (α21). In this case, from (A.1), we obtain
+(a + 2c − 3)(a − 2c − 3) = 5.
+Thus, we have either a + 2c = 4, a − 2c = 8, giving the contradiction c = −1, or a + 2c = 8, a − 2c = 4,
+giving the solution (6; 1, 1, 1, 1).
+We now deal with (α22).
+From (A.6) we obtain c + c4 − 2 ≤ 5, hence c4 ≤ 2.
+Thus (c, c4) ∈
+{(3, 2), (2, 1), (1, 0)} and using (A.1) we see that it has no integer solutions except in the first case,
+giving the solution (9; 3, 3, 3, 2).
+We now deal with (α23). As before, in this case we have c4 ≤ 0. This implies c = 2, c4 = 0. But
+then (A.1) does not have any integer solution.
+This concludes case (α2).
+Suppose we are in case (α3).
+We know that (c1, c2, c3, c4) ∈ {(1, 1, 1, 1), (2, 1, 1, 0), (3, 1, 1, 1), (3, 1, 1, 0)}. Using (A.1) we see that
+we have no integer solutions except in the last case, giving (7; 3, 1, 1, 0).
+Suppose we are in case (α4).
+Then (c1, c2, c3, c4) ∈ {(3, 2, 2, 2), (3; 2, 2, 1), (3; 2, 2, 0)} and (A.1) has no integer solutions.
+This concludes case (α) and the proof.
+□
+Lemma A.2. Let z = (a; b1, b2, b3, b4, b5, b6) ∈ Z7 with b1 ≥ b2 ≥ b3 ≥ b4 ≥ b5 ≥ b6 satisfying the
+following
+(A.7)
+a2 −
+6
+�
+i=1
+b2
+i = 10,
+3a −
+6
+�
+i=1
+bi = 6.
+Then z ∈ {(4; 1, 1, 1, 1, 1, 1), (5; 2, 2, 2, 1, 1, 1), (6; 3, 2, 2, 2, 2, 1), (7; 3, 3, 3, 2, 2, 2), (8; 3, 3, 3, 3, 3, 3)}.
+Proof. We first use the Cauchy-Scwartz’s inequality (�6
+i=1 bi)2 ≤ 6(�6
+i=1 b2
+i ) to obtain (a2−12a+32) ≤
+0 whence 4 ≤ a ≤ 8. We further observe that
+(A.8)
+6
+�
+i=1
+(b2
+i − bi) = a2 − 3a − 4.
+Also, (b2
+i − bi) ≥ 0 for all i ≥ 1, and b1 > 0 as 3a − 6 > 0 for a ≥ 4.
+Case 1: a = 4. We have �6
+i=1(b2
+i − bi) = 0 whence |bi| ≤ 1 for all i. Since �6
+i=1 bi = 6, we have bi = 1
+for all i.
+Case 2: a = 5. We have �6
+i=1(b2
+i − bi) = 6 whence |bi| ≤ 3. Also, �6
+i=1 b2
+i = 15 and �6
+i=1 bi = 9.
+Subcase 2.1) b1 = 3. In this case �6
+i=2(b2
+i − bi) = 0 whence |bi| ≤ 1 for all i ≥ 2. Consequently
+�6
+i=1 bi ≤ 8 which is a contradiction.
+Subcase 2.2) b1 ≤ 2. In this case we must have b1 = b2 = b3 = 2. Consequently �6
+i=4(b2
+i − bi) = 0
+whence |bi| ≤ 1 for all i ≥ 4 whence the only solution is z = (5; 2, 2, 2, 1, 1, 1).
+
+ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE
+27
+Case 3: a = 6. We have �6
+i=1(b2
+i − bi) = 14 whence |bi| ≤ 4. Also �6
+i=1 b2
+i = 26 and �6
+i=1 bi = 12.
+Subcase 3.1) b1 = 4. Then �6
+i=2(b2
+i − bi) = 2 whence |bi| ≤ 2 for i ≥ 2. Consequently b2 = b3 = b4 = 2.
+But then �6
+i=1 b2
+i ≥ 28 which is a contradiction.
+Subcase 3.2) b1 = 3.
+3.2.1) b2 = 3. In this case �6
+i=3(b2
+i − bi) = 2 whence |bi| ≤ 2 for i ≥ 3. Consequently, b3 = b4 = 2.
+Thus b5 + b6 = 2 and b2
+5 + b2
+6 which is a contradiction.
+3.2.2) b2 ≤ 2. In this case we have the only solution z = (6; 3, 2, 2, 2, 2, 1).
+Subcase 3.3) b1 ≤ 2. In this case bi = 2 for all i whence �6
+i=1 b2
+i = 24 which is a contradiction.
+Case 4: a = 7. We have �6
+i=1(b2
+i − bi) = 24 whence |bi| ≤ 5. Also, �6
+i=1 b2
+i = 39 and �6
+i=1 bi = 15.
+Subcase 4.1) b1 = 5. Then �6
+i=2(b2
+i − bi) = 4 whence |bi| ≤ 2 for all i ≥ 2. Consequently bi = 2 for all
+i, thus �6
+i=1 b2
+i = 45 which is a contradiction.
+Subcase 4.2) b1 = 4.
+4.2.1) b2 = 4. Then �6
+i=3(b2
+i − bi) = 0 whence |bi| ≤ 1 for all i ≥ 3. Consequently �6
+i=1 bi ≤ 12
+which is a contradiction.
+4.2.2) b2 = 3.
+4.2.2.1) b3 = 3. Then �6
+i=4(b2
+i − bi) = 0 whence |bi| ≤ 1 for i ≥ 4. Consequently �6
+i=1 bi ≤ 13
+which is a contradiction.
+4.2.2.2) b3 ≤ 2. Then bi = 2 for all i ≥ 3 whence �6
+i=1 b2
+i = 41 which is a contradiction.
+4.2.3) b2 ≤ 2. Then �6
+i=1 bi ≤ 14 which is a contradiction.
+Subcase 4.3) b1 = 3. Then b2 = b3 = 3.
+4.3.1) b4 = 3. Then �6
+i=5(b2
+i − bi) = 0 whence |bi| ≤ 1 for i ≥ 5. Consequently �6
+i=1 bi ≤ 14 which
+is a contradiction.
+4.3.2) b4 ≤ 2. Then b4 = b5 = b6 = 2. We get only one solution z = (7; 3, 3, 3, 2, 2, 2).
+Subcase 4.4) b1 ≤ 2. Then �6
+i=1 bi ≤ 12 which is a contradiction.
+Case 5: a = 8. We have �6
+i=1(b2
+i − bi) = 36 whence |bi| ≤ 6. Also, �6
+i=1 b2
+i = 54 and �6
+i=1 bi = 18.
+Subcase 5.1) b1 = 6. Then �6
+i=2(b2
+i − bi) = 6 whence |bi| ≤ 3 for i ≥ 2.
+5.1.1) b2 = 3. In this case �6
+i=3(b2
+i − bi) = 0 whence |bi| ≤ 1 for i ≥ 3. Consequently �6
+i=1 bi ≤ 13
+which is a contradiction.
+5.1.2) b2 ≤ 2. In this case �6
+i=1 bi ≤ 16 which is a contradiction.
+Subcase 5.2) b1 = 5. Then �6
+i=2(b2
+i − bi) = 16 whence |bi| ≤ 4.
+5.2.1) b2 = 4. Then �6
+i=3(b2
+i − bi) = 4 whence |bi| ≤ 2 for i ≥ 3. Thus �6
+i=1 bi ≤ 17 which is a
+contradiction.
+5.2.2) b2 = 3 which implies b3 = 3. Then �6
+i=4(b2
+i − bi) = 4 whence |bi| ≤ 2 for i ≥ 4. Consequently
+�6
+i=1 bi ≤ 17 which is a contradiction.
+5.2.3) b2 ≤ 2. Then �6
+i=1 bi ≤ 15 which is a contradiction.
+Subcase 5.3) b1 = 4.
+5.3.1) b2 = 4.
+5.3.1.1) b3 = 4. Then �6
+i=4(b2
+i − bi) = 0 whence |bi| ≤ 1 for i ≥ 4. Consequently �6
+i=1 bi ≤ 15
+which is a contradiction.
+5.3.1.2) b3 = 3 which implies b4 = 3. Thus �6
+i=5(b2
+i −bi) = 0 whence |bi| ≤ 1 for i ≥ 5. Consequently
+�6
+i=1 bi ≤ 16 which is a contradiction.
+5.3.1.3) b3 ≤ 2. Then �6
+i=1 bi ≤ 16 which is a contradiction.
+5.3.2) b2 = 3. Then b3 = b4 = b5 = 3 and b6 = 2. Consequently �6
+i=1 b2
+i = 56 which is a contradiction.
+5.3.3) b2 ≤ 2. Then �6
+i=1 bi ≤ 14 which is a contradiction.
+Subcase 5.4) b1 ≤ 3. In this case we have the only solution z = (8; 3, 3, 3, 3, 3, 3).
+□
+Angelo Felice Lopez, Dipartimento di Matematica e Fisica, Universit`a di Roma Tre, Largo San Leonardo
+Murialdo 1, 00146, Roma, Italy. e-mail lopez@mat.uniroma3.it
+Debaditya Raychaudhury, Department of Mathematics, University of Toronto, Bahen Centre, 40 St.
+George St., Room 6290, Toronto, ON M5S 2E4, Canada. email: debaditya.raychaudhury@utoronto.ca
+
diff --git a/BdE1T4oBgHgl3EQfVgTd/content/tmp_files/load_file.txt b/BdE1T4oBgHgl3EQfVgTd/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..e5d27efd8da31ef386a5cd86c9493f0244e0fa46
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+++ b/BdE1T4oBgHgl3EQfVgTd/content/tmp_files/load_file.txt
@@ -0,0 +1,2012 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf,len=2011
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='03104v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='AG]  8 Jan 2023  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  ANGELO FELICE LOPEZ* AND DEBADITYA RAYCHAUDHURY**  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We study varieties X ⊆ PN of dimension n such that TX(k) is an Ulrich vector bundle for  some k ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' First we give a sharp bound for k in the case of curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then we show that k ≤ n + 1 if  2 ≤ n ≤ 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We classify the pairs (X, OX(1)) for k = 1 and we show that, for n ≥ 4, the case k = 2  does not occur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Introduction  Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As is well known, the study of  vector bundles on X can give important geometrical information about X itself.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Regarding this, one  of the most interesting family of vector bundles associated to X and its embedding, that received a lot  of attention lately, is that of Ulrich vector bundles, that is bundles E such that Hi(E(−p)) = 0 for all  i ≥ 0 and 1 ≤ p ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The study of such bundles is closely related with several areas of commutative  algebra and algebraic geometry, and often gives interesting consequences on the geometry of X and on  the cohomology of sheaves on X (see for example in [ES, Be1, CMRPL] and references therein).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Perhaps the most challenging question in these matters is whether every X ⊆ PN carries an Ulrich  vector bundle (see for example [ES, page 543]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It comes therefore very natural to ask if usual vector  bundles associated to X can be Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, since Ulrich vector bundles are globally generated, it is  better to consider twisted versions of the usual bundles associated to X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The cases of the (twisted)  normal, cotangent, restricted tangent and cotangent bundles have been dealt with in [Lop], with an  essentially complete classification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In this paper we study the more delicate question: for which integers k one has that TX(k) is an  Ulrich vector bundle?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Ulrich vector bundles have special cohomological features, but also numerical ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This makes the  above question rather tricky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It is easy to show that k ≥ 0 unless (X, OX(1), k) = (P1, OP1(1), −2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In the case k = 0, a recent result [BMPT, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5] gives a classification: (X, OX(1)) =  (P1, OP1(3)), (P2, OP2(2)) (we will give a new and simple proof in section 8;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' another proof is given in  [C2]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand, for k ≥ 1, the question is more subtle as we will see below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In the case of curves, one sees that k = 1 is not possible (see Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i)), while the cases k = 2, 3  can be dealt with on any curve (see Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and Example 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand, the following  sharp bound holds, showing that for curves k can be as large as wanted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let X ⊆ PN be a smooth irreducible curve of genus g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich line bundle, then  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  k ≤  √8g + 1 − 1  2  and equality holds if and only if k is even and either X is one of the curves (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) lying on a smooth  cubic or X is a curve of type (k  2 +1, k +2) on a smooth quadric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, in both cases, TX(k) is an Ulrich  line bundle, hence the bound is sharp for every even k ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover, if X has general moduli, then  k ≤ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  As far as we know, only curves show this kind of behavior, meaning that k is not bounded in terms  of the dimension (a somewhat bad bound can also be given in terms of the degree, see Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As  supporting evidence, we prove the following  Research partially supported by PRIN “Advances in Moduli Theory and Birational Classification”, GNSAGA-INdAM  and the MIUR grant Dipartimenti di Eccellenza 2018-2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ** Research partially supported by a Simons Postdoctoral Fellowship from the Fields Institute for Research in Mathe-  matical Sciences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Mathematics Subject Classification : Primary 14J60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Secondary 14J35, 14J40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  1  2  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let X ⊆ PN be a smooth irreducible variety of dimension n such that 2 ≤ n ≤ 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an  Ulrich vector bundle, then k ≤ n + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We should point out that, for n ≥ 2, we know no examples with k ≥ 2 and only one example with  k = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As a matter of fact, the case k = 1 can be completely characterized, as follows  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(1) is an Ulrich vector  bundle if and only if (X, OX(1)) = (S5, −2KS5), where S5 is a Del Pezzo surface of degree 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  On the other hand, for k = 2, we have  Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(2) is not an Ulrich vector  bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We do not know what happens for k = 2, n = 3, even though some evidence suggests that it might  not be possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, for surfaces, the cases k = 2, 3 point out to the possible existence, that needs to be  further investigated, of some minimal surfaces of general type, as shown in Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and Proposition  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Finally, in any dimension, another interesting case is the one in which ωX and OX(1) are numerically  proportional.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This is dealt with in Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10, Corollaries 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11 and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Notation  Throughout the paper we work over the complex numbers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover we henceforth establish the  following  Notation 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  X is a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  H is a very ample divisor on X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  For any sheaf G on X we set G(l) = G(lH).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  d = Hn is the degree of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  C is a general curve section of X under the embedding given by H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  S is a general surface section of X under the embedding given by H, when n ≥ 2  g = g(C) = 1  2[KXHn−1 + (n − 1)d] + 1 is the sectional genus of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  For 1 ≤ i ≤ n − 1, let Hi ∈ |H| be general divisors and set Xn := X and Xi = H1 ∩ · · · ∩ Hn−i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Generalities on Ulrich bundles  We collect some well-known facts, to be used sometimes later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Definition 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let E be a vector bundle on X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We say that E is an Ulrich vector bundle for (X, H)  if Hi(E(−p)) = 0 for all i ≥ 0 and 1 ≤ p ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We have  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let E be a rank r Ulrich vector bundle for (X, H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then  (i) c1(E)Hn−1 = r  2[KX + (n + 1)H]Hn−1,  (ii) If n ≥ 2, then c2(E)Hn−2 = 1  2[c1(E)2 − c1(E)KX]Hn−2 + r  12[K2  X + c2(X) − 3n2+5n+2  2  H2]Hn−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) χ(E(m)) = rd  n!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (m + 1) · · · (m + n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) Hn(E(m)) = 0 if and only if m ≥ −n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) E∗(KX + (n + 1)H) is also an Ulrich vector bundle for (X, H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vi) E is globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vii) h0(E) = rd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (viii) E is arithmetically Cohen-Macaulay (aCM), that is Hi(E(j)) = 0 for 0 < i < n and all j ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ix) E|Y is Ulrich on a smooth hyperplane section Y of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  3  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  KXi = (KX + (n − i)H)|Xi , 1 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  By [CH, Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4(iii)] we have that  c1(E)Hn−1 = deg(E|C) = r(d + g − 1)  and using (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) on C = X1 we have  KXHn−1 = 2(g − 1) − (n − 1)d  thus giving (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (ii) observe that the exact sequences, for 1 ≤ i ≤ n − 1,  0 → TXi → (TXi+1)|Xi → H|Xi → 0  and (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) give by induction that  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  c2(S) = c2(X2) = c2(X)Hn−2 + (n − 2)KXHn−1 +  �n − 1  2  �  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  It follows from [C1, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1(2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)], (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1), and Noether’s formula 12χ(OS) − K2  S = c2(S) that  c2(E)Hn−2  = 1  2[c1(E)2 − c1(E)(KX + (n − 2)H)]Hn−2 − r  �  Hn − [KX+(n−2)]2Hn−2+c2(S)  12  �  =  = 1  2[c1(E)2 − c1(E)KX]Hn−2 − n−2  2 c1(E)Hn−1 − r  �  Hn − [KX+(n−2)H]2Hn−2+c2(S)  12  �  Now (ii) follows from the above equation by using (i) and (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Next, (iii) is [CH, Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see  (iv) observe that E is 0-regular, hence it is q-regular for every q ≥ 0 and therefore Hn(E(q − n)) = 0,  that is (iv).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, (v) follows by definition and Serre duality, while (vi) follows by definition, since E is  0-regular, and [Laz, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' For (vii), (viii) and (ix) see [ES, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] (or [Be1, (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)]) and [Be1,  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' TX(k) Ulrich in any dimension  We start by drawing some consequences on (X, H, k), of cohomological and numerical type, when  TX(k) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let (X, H) = (Pn, OPn(1)), n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(k) is an Ulrich vector bundle if and only if  n = 1 and k = −2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The assertion is obvious if (X, H, k) = (P1, OP1(1), −2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Vice versa suppose that TX(k) is an  Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  If (X, H) = (Pn, OPn(1)), it follows by [ES, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] (or [Be1, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3])  that TPn(k) ∼= O⊕n  Pn , hence 0 = det(TPn(k)) = OPn(nk + n + 1), so that 1 = −n(k + 1), giving  n = 1, k = −2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (cohomological conditions)  Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich vector bundle  we have:  (i) Either (X, H, k) = (P1, OP1(1), −2), or k ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) If n ≥ 2, then TX is aCM, that is Hi(TX(j)) = 0 for 1 ≤ i ≤ n − 1 and for every j ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In  particular Hi(TX) = 0 for 1 ≤ i ≤ n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) If k ≥ 1, then H0(TX) = 0, hence X has discrete automorphism group.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) If n ≥ 2, then X is infinitesimally rigid, that is H1(TX) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) H0(KX + (n − k − 2)H) = 0 and, if n ≥ 2, also H0(KX + (n − k − 1)H) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vi) If q(X) ̸= 0 then H0(KX + (n − k)H) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vii) If k ≤ n − 1, then pg(X) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (viii) Let a(X, H) = min{l ∈ Z : lH − KX ≥ 0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then k ≤ a(X,H)(n+2)  2n  + n+1  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Moreover H0((⌈n(2k−n−1)  n+2  ⌉ − 1)H − KX) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ix) KX − kH is not big.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since TX(k) is an Ulrich vector bundle, it is globally generated by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now if  k ≤ −1 we would have that 0 ̸= H0(TX(k)) ⊆ H0(TX(−1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  But then the Mori-Sumihiro-Wahl’s  theorem [MS, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 8], [W, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1] implies that (X, H) = (P1, OP1(2)), (Pn, OPn(1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In the first  case we have that 0 = Hi(TP1(k − 1)) = Hi(OP1(2k)) = 0 for i ≥ 0, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In the second  case apply Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now (ii) follows by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(viii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If k ≥ 1 we have that  H0(TX) ⊆ H0(TX(k − 1)) = 0, hence (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (iv) is implied by (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As for (v), recall that, as is well  known, Ω1  X(2) is globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now if H0(KX + (n − k − 2)H) ̸= 0 then we get the contradiction  0 ̸= H0(Ω1  X(2)) ⊆ H0(Ω1  X(KX + (n − k)H)) = Hn(TX(k − n))∗ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This gives the first part of (v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Similarly, if q(X) ̸= 0 and H0(KX + (n − k)H) ̸= 0 then we get the  contradiction  0 ̸= H0(Ω1  X) ⊆ H0(Ω1  X(KX + (n − k)H)) = Hn(TX(k − n))∗ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This gives (vi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now if n ≥ 2, consider Y ∈ |H| smooth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(k)|Y is an Ulrich vector bundle on  Y by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(ix), hence Hn−1(TX(k − n + 1)|Y ) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the exact sequence  0 → TY (k − n + 1) → TX(k − n + 1)|Y → OY (k − n + 2) → 0  implies that Hn−1(OY (k − n + 2)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence, setting L = KX + (n − k − 1)H, we get by Serre’s  duality that  H0(L|Y ) = H0(KY + (n − k − 2)H|Y ) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Therefore H0(L(−l)|Y ) = 0 for every l ≥ 0 and the exact sequences  0 → L(−l − 1) → L(−l) → L(−l)|Y → 0  show that h0(L(−l − 1)) = h0(L(−l)) for every l ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since this is zero for l ≫ 0, we get that they  are all zero, hence H0(KX + (n − k − 1)H) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves the second part of (v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now, to see (vii),  suppose that k ≤ n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n ≥ 2, we see that (v) gives H0(KX) ⊆ H0(KX + (n − k − 1)H) = 0,  hence (vii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n = 1 we have that k ≤ 0, hence X = P1 by (i) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Observe that  a(X, H)H − KX ≥ 0, hence (a(X, H)H − KX)Hn−1 ≥ 0 and using Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii), we get  a(X, H) ≥ n(2k − n − 1)  n + 2  This gives (viii) since, by its own definition, H0((a(X, H) − 1)H − KX) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally assume that  KX − kH is big.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Serre’s duality gives H0(TX(k)) = Hn(Ω1  X(KX − kH))∗ = 0 by Bogomolov-  Sommese vanishing [Bo, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4], contradicting Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (numerical conditions)  Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich vector bundle  we have:  (i) d = (n+2)(g−1)  nk−1  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In particular either (X, H, k) = (P1, OP1(1), −2), or g = k = 0, or g ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) k = n+1  2  +  � n+2  2nd  �  KXHn−1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' equivalently KXHn−1 = n(2k−n−1)  n+2  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) If k < n+1  2 , then X is rationally connected and Hi(OX) = 0 for every i ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) If k > n+1  2 , then −KX is not pseff.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) TX is semistable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vi) If n ≥ 2, then K2  XHn−2 ≤  2n  n−1c2(X)Hn−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vii) If n ≥ 2, then  (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 2(n + 12)K2  XHn−2 + 2(n − 12)c2(X)Hn−2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since c1(TX(k)) = −KX + nkH, we get by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(i) that  (−KX + nkH)Hn−1 = n  2  �  KXHn−1 + (n + 1)d  �  and this gives (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, using KXHn−1 = 2(g − 1) − (n − 1)d, we get that  (nk − 1)d = (n + 2)(g − 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now if nk − 1 = 0 then n = k = g = 1, but then TX(k) = OX(1) is not Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore nk − 1 ̸= 0  and d = (n+2)(g−1)  nk−1  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence g ̸= 1 and if g = 0 then either k = 0 or k ̸= 0 and in the latter case we  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  5  have that nk < 1, hence (X, H, k) = (P1, OP1(1), −2) by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Next, (v)  follows since Ulrich vector bundles are semistable by [CH, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9], hence Bogomolov’s inequality  gives (vi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (iii), suppose that k < n+1  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n ≥ 2, then (ii) gives that KXHn−1 < 0, hence X is  rationally connected by (v) and [BMQ, Main Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='] (see also [CP, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence, as is well known,  Hi(OX) = 0 for every i ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n = 1 then k ≤ 0 and X = P1 by (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus we get (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If k > n+1  2 ,  then either n = 1 and g ≥ 2 by (i), so that −KX is not pseff, or n ≥ 2 and (ii) gives that KXHn−1 > 0,  hence again −KX is not pseff and we get (iv).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (vii), observe that  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  c2(TX(k))Hn−2 = c2(X)Hn−2 − k(n − 1)KXHn−1 +  �n  2  �  k2d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  From Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(ii), we get  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  c2(TX(k))Hn−2 =  �n2k2  2  − n  24  �  3n2 + 5n + 2  ��  d−3nk  2 KXHn−1+  �  1 + n  12  �  K2  XHn−2+ n  12c2(X)Hn−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Combining (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1), (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) and (ii), we obtain (vii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Definition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' For n ≥ 1 we denote by Qn a smooth quadric in Pn+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let (X, H) = (Qn, OQn(1)), n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(k) is not an Ulrich vector bundle for any  integer k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since g = 0, it follows by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) that k = 0 and 2 = d = n + 2, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We will use the nef value of (X, H):  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3)  τ(X, H) = min{t ∈ R : KX + tH is nef}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We observe that in [BS, Def.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3] the nef value is defined only when KX is not nef.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other  hand, it makes sense and it will be used, throughout this paper, also when KX is nef.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  A very useful observation is the following.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich  vector bundle, then Ω1  Y (KX |Y +(n+1−k)H|Y ) is globally generated for any smooth subvariety Y ⊆ X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Moreover:  (i) If ±(KX + n(n+1−2k)  n+2  H) is pseff, then KX ≡ n(2k−n−1)  n+2  H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) τ(X, H) ≥ n(n+1−2k)  n+2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) τ(X, H) ≤ n −  nk  n+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In particular, if KX is not nef, then k ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) If k ≥ n + 1, then KX is ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that Ω1  X(KX + (n + 1 − k)H) is Ulrich and globally generated by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) and (vi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Since Ω1  X(KX + (n + 1 − k)H) surjects onto Ω1  Y (KX |Y + (n + 1 − k)H|Y ), the latter is also globally  generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover so is det(Ω1  X(KX+(n+1−k)H) = (n+1)KX+n(n+1−k)H, hence we get (iii) and,  if k ≥ n+2, we also deduce that KX is ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand, if k = n+1, then Ω1  X(KX) is Ulrich,  and we claim that det(Ω1  X(KX)) = (n + 1)KX is ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In fact, if not, then [LS, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1] implies that  there is a line L ⊂ X such that Ω1  X(KX)|L is trivial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence (n + 1)KX · L = deg(Ω1  X(KX)|L) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But  then we have a surjection Ω1  X(KX)|L → Ω1  L, contradicting the fact that Ω1  L is not globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This proves (iv).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As for (i) and (ii), set q = n(n+1−2k)  n+2  , so that (KX + qH)Hn−1 = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now if ±(KX + qH) is pseff, then KX + qH ≡ 0 by [FL2, Cor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='15] (see also [FL1, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7]), thus  proving (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, (i) implies that either KX ≡ −qH and then τ(X, H) = q, or KX + qH is not pseff,  hence not nef.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore, in the latter case, τ(X, H) > q, proving (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich  vector bundle we have that  k ≤ (n + 2)(d − 4) + 4  4n  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have X ⊂ PH0(H) = PN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If N = n then (X, H) = (Pn, OPn(1)) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 gives that  n = 1 and k = −2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since d = 1 we have that k = −2 ≤ − 5  4 = (n+2)(d−4)+4  4n  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  6  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  We now show that it cannot be that N = n + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that N = n + 1, so that d ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n = 1 we  have that KX = (d − 3)H, g =  �d−1  2  �  and k = 3(d−3)  2  + 1 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now 0 = H0(TX(k − 1)) =  H0((−d + 2 + k)H) and therefore −d + 2 + k ≤ −1, giving the contradiction d ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence n ≥ 2 and  since C ⊂ P2 we have that g − 1 = d(d−3)  2  and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) implies that d = 2(nk−1)  n+2  + 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other  hand Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) gives that  0 = H0(KX + (n − k − 1)H) = H0((d − k − 3)H)  and therefore  2(nk − 1)  n + 2  − k ≤ −1  that is k(n − 2) + n ≤ 0, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Therefore N ≥ n + 2 and C ⊂ PN−n+1 can be projected isomorphically to a non-degenerate smooth  irreducible curve in P3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Castelnuovo’s bound gives that g − 1 ≤ d(d−4)  4  and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) implies  the required bound on k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  A nice consequence of the above lemmas is the following.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' There does not exist any (X, H, k) with TX(k) an Ulrich vector bundle, when:  (i) KX ≡ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) ±KX is pseff and k = n+1  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Under hypothesis (ii), we get from Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6(i) that KX ≡ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus we will be done if we prove  (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume next that KX ≡ 0, so that k = n+1  2  by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) and n ≥ 3 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since  H − KX is ample, it follows by Kodaira vanishing that Hi(H) = Hi(KX + H − KX) = 0 for i > 0,  hence  h0(KX + H) = χ(KX + H) = χ(H) = h0(H) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  On the other hand, Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) gives that h0(KX + n−3  2 H) = 0, whence, if n ≥ 5, we get the  contradiction h0(KX + H) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  It remains to consider the case n = 3, k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that pg(X) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vii) and q(X) = 0,  for otherwise Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vi) gives that h0(KX + H) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore χ(OX) ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand  χ(OX) =  1  24c1(X)c2(X) = 0, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We now prove Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By the Hodge index theorem we have that H2  |SK2  S ≤ (H|SKS)2, that is  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4)  dK2  XHn−2 ≤ (KXHn−1)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Using Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(vi), (vii) and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) we obtain that  0 = (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 2(n + 12)K2  XHn−2 + 2(n − 12)c2(X)Hn−2 ≤  ≤ (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 3n2 + 11n + 12  n  K2  XHn−2 ≤  ≤ (12kn − 12k2 + 12k − 3n2 − 5n − 2)nd + 3n2 + 11n + 12  nd  (KXHn−1)2  which, using Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) becomes  4nk2 − 4n(n + 1)k − 3n2 − 7n − 4 ≤ 0  giving  k ≤ n2 + n +  √  n4 + 5n3 + 8n2 + 4n  2n  < n + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  The case k = 0 is known:  Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' ([BMPT, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5])  Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX is an Ulrich vector bundle  if and only if (X, H) = (P1, OP1(3)), (P2, OP2(2)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  7  We will give a quick alternative proof in section 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Next we study the case when KX and H are proportional.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that the  numerical classes of H and KX are proportional and that either  (i) 1 ≤ n ≤ 11 and either k ≤ n+1  2  or k ≥ n + 2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' or  (ii) n = 12, or  (iii) n ≥ 13 and k ̸∈ {n + 2, n + 3}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then TX(k) is Ulrich if and only if (X, H, k) is one of the following:  (1) (P1, OP1(1), −2),  (2) (P1, OP1(3), 0),  (3) (P2, OP2(2), 0),  (4) (S5, −2KS5, 1), where S5 is a Del Pezzo surface of degree 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In the cases (1)-(4) we have that TX(k) is Ulrich by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9 and Theorem  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Vice versa, suppose that the numerical classes of H and KX are proportional and that we are under  one of hypotheses (i), (ii) or (iii) and that TX(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Observe that, since N 1(X) is a torsion free finitely generated abelian group, we can find an ample  primitive divisor A and some r, s ∈ Z such that s > 0, H ≡ sA and KX ≡ −rA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In particular, Lemma  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) gives  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5)  r(n + 2) = n(n + 1 − 2k)s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  If k ≤ 0 we are in cases (1)-(3) by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(i) and Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence assume that k ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note  that Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8 shows that k ̸= n+1  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  If (ii) or (iii) holds, since the numerical classes of H and KX are proportional, Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(vi), (ii)  and (vii) imply that  4nk2 − 4n(n + 1)k − 3n2 − 7n − 4 ≥ 0  so that k > n + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This is a contradiction under hypothesis (ii) by Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Under hypothesis (iii),  we get that k ≥ n + 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then it follows by (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5) that  −r − ks = (n − 2)k − n2 − n  n + 2  s ≥ n − 8  n + 2s > 0  hence KX − kH = (−r − ks)A is ample, contradicting Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(ix).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus it remains to consider  hypothesis (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now assume (i), so that n ≥ 2 and Theorem 2 implies that it cannot be that k ≥ n + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence  k < n+1  2  and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) implies that X is Fano.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently, the numerical and linear equivalence  for divisors coincide on X and then KX = −rA and H = sA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We can also assume that r ≤ n − 1, for  otherwise, as is well known, (X, H) = (Pn, OPn(1)), (Qn, OQn(1)), contradicting Lemmas 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Next, set PA(t) := χ(KX + tA), so that PA(t) = h0(KX + tA) whenever t ≥ 1 is an integer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By  Riemann-Roch (see for example [Ho, eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (1), p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2], we have  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6)  PA(t) = An  n!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' tn + An−1KX  2(n − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='tn−1 + An−2(K2  X + c2(X))  12(n − 2)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  tn−2 + · · · + (−1)nχ(OX).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Note that n is even, for otherwise n and n + 2 are coprime, and consequently n divides r by (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5),  hence r ≥ n, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Set n = 2m, where 1 ≤ m ≤ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  If m = 1 we have that n = 2, k = 1 and we are in case (4) by Theorem 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We will now exclude the remaining cases for m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Note that we can rewrite (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5) as  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7)  (m + 1)r = m(2m − 2k + 1)s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 1: m = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case k ≤ 2 and r ≤ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (1a): k = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that r = 2s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (r, s) = (2, 1), contradicting Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (1b): k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 2s = 3r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (r, s) = (2, 3) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) shows that h0(A) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This contradicts [A, Lemma 2] or [K, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  8  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Case 2: m = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case k ≤ 3 and r ≤ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (2a): k = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 4r = 15s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 15 divides r which is clearly impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (2b): k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 9s = 4r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 9 divides r which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (2c): k = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 3s = 4r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (r, s) = (3, 4) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) shows that h0(KX+8A) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This is a contradiction by [GL, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2], as KX + 8A is base-point-free.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 3: m = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case k ≤ 4 and r ≤ 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (3a): k = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 5r = 28s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 28 divides r which is clearly impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (3b): k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 4s = r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (r, s) = (4, 1) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) shows h0(KX + 5A) =  h0(H) = 0, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (3c): k = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 12s = 5r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 12 divides r which is absurd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (3d): k = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 4s = 5r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, (r, s) = (4, 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We have KX = −4A and H = 5A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence H0(KX + 15A) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then  PA(1) = PA(2) = PA(3) = PA(5) = PA(10) = PA(15) = 0,  PA(0) = PA(4) = 1  and  PA(t) = A8  8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (t − 1)(t − 2)(t − 3)(t − 5)(t − 10)(t − 15)(t2 + at + b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Therefore  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8)  1 = PA(0) = A8  8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (4500b) =⇒ A8  8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b =  1  4500  and calculating the coefficient of t7 in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) we get  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9)  A8  8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (a − 36) = A7KX  2(7!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=')  =⇒ a = 20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We also know that PA(4) = 1 and that gives us  −A8  8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (396)(16 + 4a + b) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We simplify the above using (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8) and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9) to obtain  −38016A8  8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' = 1 + 396  4500  which is clearly absurd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 4: m = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case k ≤ 5 and r ≤ 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (4a): k = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 2r = 15s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 15 divides r which is impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (4b): k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 35s = 6r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 35 divides r which is also impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (4c): k = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 25s = 6r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, 25 divides r which is also impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (4d): k = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 5s = 2r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (r, s) = (5, 2) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) shows that h0(KX +10A) =  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then  PA(1) = PA(2) = PA(3) = PA(4) = PA(6) = PA(8) = PA(10) = 0,  PA(0) = PA(5) = 1  so that we obtain  PA(t) = A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (t − 1)(t − 2)(t − 3)(t − 4)(t − 6)(t − 8)(t − 10)(t3 + at2 + bt + c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Therefore  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10)  1 = PA(0) = −A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (11520c) = 1 =⇒ A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' c = −  1  11520.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  and calculating the coefficient of t9 in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) we get  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11)  A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (a − 34) = A9KX  2(9!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=')  =⇒ a = 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We also know that PA(5) = 1 and that gives us  −A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (360)(125 + 25a + 5b + c) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  9  We simplify the above using (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10) and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11) to obtain  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12)  A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b =  1  5(11520) −  1  5(360) − 70A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Finally, calculating the coefficient of t8 in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) we get  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='13)  A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (b − 34a + 463) = A8(K2  X + c2(X))  12(8!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=')  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We simplify (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='13) using (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11) and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12) to obtain  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='14)  67A10 + 5A8c2(X) + 1302 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  On the other hand, Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(vii) shows that  115A10 = A8c2(X)  and combining with (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='14), we get that A10 is negative, which is clearly impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (4e): k = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We see that 5s = 6r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (r, s) = (5, 6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have KX = −5A and H = 6A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Again  H0(KX + 24A) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then  PA(1) = PA(2) = PA(3) = PA(4) = PA(6) = PA(12) = PA(18) = PA(24) = 0,  PA(0) = PA(5) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus, we obtain  PA(t) = A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (t − 1)(t − 2)(t − 3)(t − 4)(t − 6)(t − 12)(t − 18)(t − 24)(t2 + at + b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='15)  1 = PA(0) = A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (746496b) =⇒ A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b =  1  746496.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  calculating the coefficient of t9 in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) we get  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='16)  A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (a − 70) = A9KX  2(9!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=')  =⇒ a = 45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We also know that PA(5) = 1 and that gives us  A10  10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (41496)(25 + 5a + b) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We simplify the above using (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='15) and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='16) to obtain  A10 =  �705000  746496  �  (10!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=')  which is clearly absurd since A10 is an integer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Corollary 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that KX = eH, e ∈ Z (hence, in particular, if Pic(X) = ZH).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(k)  is Ulrich if and only if (X, H, k) = (P1, OP1(1), −2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This follows by [Lop, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1(i)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We give another proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have that e = n(2k−n−1)  n+2  by  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If k ≤ n+1  2  it follows by Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10 that (X, H, k) = (P1, OP1(1), −2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now assume  that k > n+1  2 , so that e ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n ≥ 2, Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) gives that k ≥ n + e, hence k(n − 2) + n ≤ 0, a  contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then n = 1 and e = 2(k−1)  3  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But 0 = H0(TX(k − 1)) = H0((k − 1 − e)H), hence e ≥ k,  so that k ≤ −2, contradicting k > 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Corollary 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 2 with TX(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose that there is an ample line bundle A on X such that KX = rA, H = sA for some r, s ∈ Z  (hence, in particular, if Pic(X) ∼= Z).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let m(H, A) := min{m ≥ 0 : H0(mH + qA) ̸= 0 for all q ≥ 1}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then:  (i) m(H, A) > (n−2)k−2  n+2  and, if n ≥ 3, then k < (n+2)m(H,A)+2  n−2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) If A is effective, then n = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) If m(H, A) ≤ n − 3, then n ≤ 11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  10  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Observe first that, if n ≥ 3, then (n−2)k−2 ≥ k−2 ≥ 0: In fact if k ≤ 1 we have a contradiction  by Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) implies that  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='17)  r(n + 2) = n(2k − n − 1)s  and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(v) gives  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='18)  0 = H0(KX + (n − k − 1)H) = H0((nk − 2k − 2)s  n + 2  A).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  To see (i), notice that it is obvious for n = 2, for m(H, A) ≥ 0 by definition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n ≥ 3 we see by (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='18)  that (nk−2k−2)s  n+2  ∈ Z and we can write (nk−2k−2)s  n+2  = as+b for some a, b ∈ Z with a ≥ 0, 0 ≤ b < s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since  H0(aH + bA) = 0 by (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='18), we get that  (n − 2)k − 2  n + 2  − 1 < a ≤ m(H, A) − 1  giving (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now suppose that A is effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n ≥ 3 we know that (n − 2)k − 2 ≥ 0, contradicting  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='18).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (iii), notice that if n ≥ 12, then k ≥ n + 2 by Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10(ii) and (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Hence (n−2)k−2  n+2  > n − 3 and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='18) gives that  0 = H0((nk − 2k − 2)s  n + 2  A) = H0((n − 3)H + qA)  for some q ≥ 1, contradicting the hypothesis m(H, A) ≤ n − 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Curves  Throughout this section we will have that X ⊆ PN is a smooth irreducible curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  It follows by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) and Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9 that if n = 1 and TX(k) is an Ulrich line bundle, then  (X, H, k) = (P1, OP1(1), −2), (P1, OP1(3), 0) or k ≥ 2 and g ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We will give below examples with k = 2, 3, essentially on any curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then we will give a sharp bound  on k depending on the genus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  The case k = 2 can be characterized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that g ≥ 3 when k = 2 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(2) is Ulrich if and only if there  exists M ∈ Pic(X) such that Hi(M) = 0 for i ≥ 0 and H = KX + M is very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This occurs if and  only if g ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(2) is Ulrich, set M = H −KX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Hi(M) = Hi(TX(1)) = 0 for i ≥ 0 and KX +M = H  is very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Vice versa let M ∈ Pic(X) be such that Hi(M) = 0 for i ≥ 0 and H = KX + M is very  ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Hi(TX(1)) = Hi(M) = 0 for i ≥ 0, so that TX(2) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose that g ≥ 3 and let M ∈ Pic(X) be such that Hi(M) = 0 for i ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We claim that  H := KX + M is very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In fact deg M = g − 1 by Riemann-Roch, hence deg H = 3g − 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If g ≥ 4,  then deg H ≥ 2g + 1, hence H is very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If g = 3 we have that deg H = 2g and, as is well known,  H is very ample unless H = KX + P + Q for two points P, Q ∈ X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But then M = P + Q is effective,  a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Instead, if g = 2 we have that deg(KX + M) = 3 > 2g − 2, hence h0(KX + M) = 2  by Riemann-Roch.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let P + Q + R be an effective divisor linearly equivalent to KX + M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then  KX + M − P − Q ∼ R, hence h0(KX + M − P − Q) = 1 and therefore KX + M is not very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Example 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The case k = 3 occurs on any curve X with (necessarily) odd genus g ≥ 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This was  suggested to us by E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Sernesi, whom we thank.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let d = 3(g−1)  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We claim that a general H ∈ Picd(X) is very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In fact, first observe that  H1(H) = 0, for otherwise KX − H ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But KX − H is a general line bundle of degree g−1  2  ≤ g − 1,  hence h0(KX − H) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now, if H were not very ample, there will be two points p, q ∈ X such that  h0(H − p − q) ≥ h0(H) − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But this can be rewritten, by Riemann-Roch, as h1(H − p − q) ≥ 1, that  is KX − H + p + q ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence there are some points p1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' , p g+3  2  ∈ X such that  KX − H + p + q ∼ p1 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' + p g+3  2  that is  H ∼ KX − p1 − .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' − p g+3  2  + p + q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  11  This means that H is in the image of the morphism h : X  g+7  2  → Picd(X) sending (p1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' , p g+3  2 , p, q) to  KX − p1 − .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' − p g+3  2  + p + q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But dim Imh ≤ g+7  2  < g, contradicting that H is general.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves  that there is a non-empty open subset W of Picd(X) such that any H ∈ W is very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Consider the surjective morphism ψ : Picd(X) → Pic3g−3(X) given by ψ(L) = 2L and the isomor-  phism ϕ : Pic3g−3(X) → Picg−1(X) given by ϕ(L) = L − KX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let U be the non-empty open subset  of Picg−1(X) such that Hi(M) = 0 for i ≥ 0 for any M ∈ U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now let H ∈ ψ−1(ϕ−1(U)) ∩ V ∩ W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then H is very ample and 2H = KX + M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In the embedding given by H we have that Hi(TX(2)) =  Hi(−KX + 2H) = Hi(M) = 0 for i ≥ 0, hence TX(3) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If k ≥ 1 and g − 1 is a prime number, then k ∈ {2, 4}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) we get that (k − 1)d = 3(g − 1) and g ≥ 2, hence d ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If 3 does not divide  k − 1 we get that 3 divides d and (k − 1)d  3 = g − 1, so that k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If 3 divides k − 1 we get that  k−1  3 d = g − 1, so that k = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Example 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Every odd k ≥ 3 occurs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let E be an elliptic curve, let D be a divisor of degree 3 on E and let S = E × P1 with two  projections π1 : S → E, π2 : S → P1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Set C0 = π∗  2(OP1(1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then H = C0 + π∗  1D is very ample on S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let M ∈ Pic0(E) be not 2-torsion and let B = k−1  2 D + M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Again H1 := (k + 2)C0 + π∗  1B is very ample  on S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Set  L = −KS + (k − 1)H = (k + 1)C0 + π∗  1(2B − 2M)  so that  L − H1 = −C0 + π∗  1(B − 2M)  while  L − 2H1 = −(k + 3)C0 + π∗  1(−2M)  and it is easily seen by the K¨unneth formula, that Hi(L − pH1) = 0 for i ≥ 0, 1 ≤ p ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence, if  X ∈ |H1| is a smooth irreducible curve, the exact sequence  0 → L − 2H1 → L − H1 → TX(k − 1) → 0  shows that Hi(TX(k − 1)) = 0 for i ≥ 0, that is TX(k) is an Ulrich line bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We now give a bound for k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We first analyze a special case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We use the notation (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b1, b2, b3, b4, b5, b6) ∈ Z7 for the divisor  aε∗L − �6  i=1 biEi on a smooth cubic W ⊂ P3, where ε : W → P2 is the blow up in six points, no three  collinear and not on a conic, with exceptional divisors Ei and L is a line in P2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊂ P3 be a smooth irreducible curve of genus 3 and degree 6 lying on a smooth cubic  W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(2) is Ulrich if and only if X is linearly equivalent to one of the following divisors on W:  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  (4;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1, 1, 1), (5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 2, 1, 1, 1), (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 2, 2, 2, 2, 1), (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 2, 2, 2), (8;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 3, 3, 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let D = −KW .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We have that D · X = 6 and X2 = 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus Riemann-Roch gives that  χ(2D − X) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Further, D(2D − X) = 0, whence H0(2D − X) = 0, for otherwise X ∼ 2D and then  X2 = 12, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, D(−3D + X) = −3, whence H0(−3D + X) = 0, which, be Serre’s  duality, is H2(2D − X) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus, also H1(2D − X) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the exact sequence  0 → 2D − 2X → 2D − X → TX(1) → 0  gives that  h1(TX(1)) = h2(2D − 2X) = h0(3KW + 2X)  by Serre’s duality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since deg TX(1) = 2, we deduce by Riemann-Roch, that TX(2) is Ulrich if and only  if H1(TX(1)) = 0, hence  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  TX(2) is Ulrich if and only if H0(3KW + 2X) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b1, · · · , b6) with b1 ≥ b2 ≥ · · · ≥ b6 ≥ 0 be the class of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It follows from the assumption on  degree and genus that (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7) holds, whence X is as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) by Lemma A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Using (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2), it remains to  show that H0(3KW + 2X) = 0 in all of these cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  12  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  In case (4;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1, 1, 1), we have that 3KW + 2X = (−1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1, 1, 1) is clearly not effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In case (5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 2, 1, 1, 1), we have that 3KW + 2X = (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' −1, −1, −1, 1, 1, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If it were effective, then  so would be (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 0, 0, 0, 1, 1, 1), a contradiction since no three blown-up points are collinear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In case (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 2, 2, 2, 2, 1), we have that 3KW + 2X = (3;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 1, 1, 1, 1, −1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume it is effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In-  tersecting with (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 0, 0, 0, 0) we see that (2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 0, 1, 1, 1, −1) must be effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Intersecting the latter  with (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 0, 1, 0, 0, 0) we conclude that (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 0, 0, 1, 1, −1) must be effective, hence also (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 0, 0, 1, 1, 0),  a contradiction since no three blown-up points are collinear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In case (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 2, 2, 2), we have that 3KW + 2X = (5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 1, 1, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume it is effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In-  tersecting with (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 0, 0, 0, 0) we see that (4;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 3, 1, 1, 1) must be effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Intersecting the latter  with (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 0, 1, 0, 0, 0) we conclude that (3;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 2, 2, 1, 1, 1) must be effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally, intersecting with  (1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 0, 1, 1, 0, 0, 0) we conclude that (2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1, 1, 1) must be effective, a contradiction since the blown-  up points do not lie on a conic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In case (8;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 3, 3, 3), we have that 3KW +2X = (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 3, 3, 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Observe that D(3KW +2X) = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus, if 3KW + 2X were effective, it would contain a divisor Γ that is either irreducible, or is a union  of three lines, or is a union of a line and a conic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now pa(Γ) = −3, hence Γ is not irreducible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the  other hand, since the first coefficient of a line in W is at most 2 and of a conic at most 3, we see that  Γ, whose first coefficient is 7, is not a union of three lines nor of a line and a conic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This contradiction  shows that 3KW + 2X is not effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Now we give the sharp bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' First assume that g = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) gives that k ≤ 0, that is the required  bound, and if equality holds, then Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9 shows that X is a curve of type (1, 2) on a smooth  quadric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus, by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), we can now assume that g ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Observe that h0(H) ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In fact, the only possibility remaining is that h0(H) = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But then KX =  (d−3)H, g =  �d−1  2  �  and k = 3(d−3)  2  +1 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now 0 = H0(TX(k −1)) = H0((−d+2+k)H)  and therefore −d + 2 + k ≤ −1, giving the contradiction d ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now, if X has general moduli, since it has a g3  d, the Brill-Noether theorem implies that ρ(g, 3, d) ≥ 0,  that is d ≥ 3g+12  4  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) we get that 3(g−1)  k−1  ≥ 3g+12  4  , that gives k ≤ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves the last  assertion of the theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Turning to the first assertion, let X ⊆ PN be a smooth irreducible curve of genus g ≥ 2 such that  TX(k) is an Ulrich line bundle and assume that  k ≥  √8g + 1 − 1  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Using Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), the above inequality can be rephrased as  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3)  g ≥ 2  9d2 − d + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Consider a general projection X′ of X to P3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that X′ ∼= X, hence TX′(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We first observe  that X′ cannot be a complete intersection (hence, in particular, X′ is nondegenerate), for otherwise  TX′(k) = lH for some l ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now TX′(k), being Ulrich, is globally generated by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vi), hence  l ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also 0 = H0(TX′(k − 1)) = H0((l − 1)H) and therefore l = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vii) gives that  d = h0(TX′(k)) = 1, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Using Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) and Castelnuovo’s bound, we get that either (d, g, k) = (6, 3, 2) or d ≥ 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose that d ≥ 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We aim to show that X′ must lie on a smooth quadric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  To this end, observe that (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) imply that  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4)  g >  �  1  6d(d − 3) + 1  if d ≡ 0 (mod 3)  1  6d(d − 3) + 1  3  if d ≡ 1, 2 (mod 3)  unless d = 9 and g = 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But in the latter case it is easy to show that if X′ does not lie on a quadric,  then it is a complete intersection of two cubics, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) and [Ha2, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2]  give that X′ lies on a quadric Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover Q is smooth, for otherwise it must be a cone, d = 2b + 1 is  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  13  odd and g = b2 − b by [Ha1, Ex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But then Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) gives that 4(k − 1) = 6b − 9 −  3  2b+1,  and therefore b = 1, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus X′ is a curve of type (a, b) on Q, with 2 ≤ a ≤ b.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In particular X′ is linearly normal, hence  X = X′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In the exact sequence  0 → OQ(k + 1 − 2a, k + 1 − 2b) → OQ(k + 1 − a, k + 1 − b) → TX(k − 1) → 0  since H0(TX(k − 1)) = 0, we get that  H0(OQ(k + 1 − 2a, k + 1 − 2b)) = H0(OQ(k + 1 − a, k + 1 − b))  hence k + 1 − b ≤ −1, for otherwise k + 1 − a ≥ k + 1 − b ≥ 0, but then X is a base-component of  |OQ(k + 1 − a, k + 1 − b)|, contradicting the fact that this linear system is base-point-free.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore  b ≥ k + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) can be rewritten now as  (a + b)(k − 1) = 3((a − 1)(b − 1) − 1)  that is  a =  b(k + 2)  3b − k − 2  and it is readily seen that b ≥ k + 2 is equivalent to a ≤ k  2 + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore b ≥ 2a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But the maximum  genus of a curve of type (a, b) with b ≥ 2a and degree d is attained when b = 2  3d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore  g ≤ (1  3d − 1)(2  3d − 1) = 2  9d2 − d + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This shows that the inequality in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) cannot be strict, and therefore g ≤ 2  9d2−d+1, which is equivalent  to (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover, if equality holds in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1), then it holds in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) and therefore X is a curve of type  (a, b) with b = 2  3d, hence b = 2a and 2a = b ≥ k + 2 ≥ 2a, so that k is even, a = k  2 + 1 and b = k + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Next consider the only remaining case, (d, g, k) = (6, 3, 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Again X′ is linearly normal, hence X = X′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also we have equality in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) and if X lies on a quadric,  then it must be of type (2, 4) and we are done in this case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose therefore that X does not lie on  a quadric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then it is easily seen that JX/P3(3) is 0-regular, hence globally generated, and we get that  X is contained in a smooth cubic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore X is one of the curves (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) by Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5 and TX(2) is  Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Finally, to show that the bound (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) is sharp for every even k ≥ 0, let X be a curve of type  (k  2 + 1, k + 2) on a smooth quadric Q ⊂ P3, so that k =  √8g+1−1  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It remains to show that TX(k) is  Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Set k = 2c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have  TX(k − 1) = −KX + (k − 1)H = OQ(c, −1)|X  and the exact sequence  0 → OQ(−1, −2c − 3) → OQ(c, −1) → OQ(c, −1)|X → 0  shows that Hi(OQ(c, −1)|X) = 0 for i ≥ 0, since Hi(OQ(c, −1)) = Hi(OQ(−1, −2c − 3)) = 0 for i ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Hence TX(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Surfaces  Throughout this section we will have that X ⊆ PN is a smooth irreducible surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We start by a characterization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(k) is an Ulrich vector bundle if  and only if  (i) d = 4(g−1)  2k−1  (ii) HKX = (2k−3)d  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) K2  X = 5χ(OX) + (k−1)(k−2)d  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) H0(TX(k − 1)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) H2(TX(k − 2)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that (i) and (ii) are equivalent, since HKX = 2(g − 1) − d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now (ii) and (iii) are the  conditions (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) in [C1, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence the lemma follows by loc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' cit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  14  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Now we show the possible cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proposition 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich vector bundle,  the following hold:  (i) 0 ≤ k ≤ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Moreover, either  (ii) k = 0 and (X, H) = (P2, OP2(2)), or  (iii) k = 1 and X is a Del Pezzo surface of degree 5, or  (iv) k = 2, q = 0 and X is a minimal surface of general type, or  (v) k = 3, X is a minimal surface of general type with 2KX ≡ 3H, K2  X = 9d  4 , χ(OX) = d  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover  X is a ball quotient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have that k ≥ 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now H1(TX) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(iv), that is X is  infinitesimally rigid and [BC, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3] implies that either X is a minimal surface of general type or  X is a Del Pezzo surface of degree j ≥ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In the latter case we have that HKX < 0 hence either k = 0  and we get (ii) by Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9, or k = 1 and K2  X = 5 by Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1(ii),(iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This gives (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the  other hand, if X is a minimal surface of general type then HKX > 0, hence k ≥ 2 by Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Next, the Hodge index theorem H2K2  X ≤ (HKX)2 can be rewritten, using Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1(ii),(iii) as  χ(OX) ≤ (2k2 − 6k + 5)d  20  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Similarly, the Bogomolov-Miyaoka-Yau inequality K2  X ≤ 9χ(OX) can be rewritten as  χ(OX) ≥ (k2 − 3k + 2)d  8  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Combining we get that  (k2 − 3k + 2)d  8  ≤ (2k2 − 6k + 5)d  20  and this gives that k ≤ 3 and moreover that, if k = 3, then equality holds in both inequalities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence,  when k = 3 we have, as is well known, that X is a ball quotient and that H2KX ≡ (HKX)H, that is  2KX ≡ 3H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then K2  X = 9d  4 and χ(OX) = d  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (i) and (v) are proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Alternatively (i) follows  by Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (iv) observe that since k = 2 we have by the above that X is a minimal surface  of general type.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now if pg = 0 then q = 0 by [Be2, Lemma VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If pg ̸= 0 we have  an inclusion H0(Ω1  X) ⊆ H0(Ω1  X(KX)) hence q = h0(Ω1  X) ≤ h0(Ω1  X(KX)) = h2(TX) = 0 since TX(2) is  Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves (iv).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We now characterize the case k = 1 for surfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Theorem 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then TX(1) is an Ulrich vector bundle if  and only if X is a Del Pezzo surface of degree 5 and H = −2KX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover in the latter case TX(1) is  very ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(1) is an Ulrich vector bundle, then Proposition 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2 implies that X is a Del Pezzo surface  of degree 5 and H2 + 2HKX = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let ε : X → P2 be the blow-up map, with exceptional divisors Ei  over the points Pi ∈ P2, 1 ≤ i ≤ 4 and let L be a line in P2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then we can write  H ∼ aε∗L −  4  �  i=1  biEi  and, as H is very ample, we have, without loss of generality,  b1 ≥ b2 ≥ b3 ≥ b4 ≥ 1, a ≥ b1 + b2 + 1  and H2 + 2HKX = 0 is  a2 − 6a + 4 =  4  �  i=1  (bi − 1)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Setting ci = bi − 1, we get by Lemma A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 the following possibilities:  (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b1, b2, b3, b4) ∈ {(6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 1, 1, 1), (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 2, 2), (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4, 2, 2, 1), (9;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4, 4, 4, 3)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  15  In the case (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 2, 2) we have that H = −2KX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We now exclude the other cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let H = 6ε∗L − 3E1 − E2 − E3 − E4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We will prove that h2(TX(−1)) = h0(Ω1  X(H + KX)) ̸= 0, so  that TX(1) cannot be an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To this end observe that, since ε∗Ω1  P2 ⊂ Ω1  X, we will be  done in this case if we prove that  H0(ε∗Ω1  P2(H + KX)) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now H + KX = 3ε∗L − 2E1, hence  H0(ε∗Ω1  P2(H + KX)) ∼= H0(IZ ⊗ Ω1  P2(3))  where Z ⊂ P2 is the 0-dimensional subscheme of length 2 supported on P1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally  h0(IZ ⊗ Ω1  P2(3)) ≥ h0(Ω1  P2(3)) − 6 = 2 > 0  and we are done in this case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Consider now the exact sequences, for any 1 ≤ i ≤ 4,  0 → OEi(−Ei) → Ω1  X|Ei → Ω1  Ei → 0  that is  0 → OP1(1) → Ω1  X|Ei → OP1(−2) → 0  from which we get, for any 1 ≤ i ≤ 4, that  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  h1(Ω1  X|Ei) = 1  and  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  H1(Ω1  X |Ei ⊗ OP1(2)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In the two remaining cases we will prove that h1(TX(−1)) = h1(Ω1  X(H + KX)) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let H = 7ε∗L − 4E1 − 2E2 − 2E3 − E4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Note that H + KX − E4 + E1 = 4ε∗L − 2E1 − E2 − E3 − E4 is very ample by [DR, Cor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6], hence  H2(Ω1  X(H + KX − E4 + E1)) = 0  by Bott vanishing [T, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then the exact sequence  0 → Ω1  X(H + KX − E4) → Ω1  X(H + KX − E4 + E1) → Ω1  X|E1(H + KX − E4 + E1) → 0  and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) imply that H2(Ω1  X(H + KX − E4)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the exact sequence  0 → Ω1  X(H + KX − E4) → Ω1  X(H + KX) → Ω1  X|E4(H + KX) → 0  and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) imply that  h1(Ω1  X(H + KX)) ≥ h1(Ω1  X |E4(H + KX)) = h1(Ω1  X|E4) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let H = 9ε∗L − 4E1 − 4E2 − 4E3 − 3E4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let C ∈ |ε∗L − E2 − E3| be the strict transform of a line through P2 and P3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that H + KX −  C + E1 = 5ε∗L − 2E1 − 2E2 − 2E3 − 2E4 is very ample by [DR, Cor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6], hence  H2(Ω1  X(H + KX − C + E1)) = 0  by Bott vanishing [T, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then the exact sequence  0 → Ω1  X(H + KX − C) → Ω1  X(H + KX − C + E1) → Ω1  X|E1(H + KX − C + E1) → 0  and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) imply that H2(Ω1  X(H + KX − C)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the exact sequence  0 → OC(−C) → Ω1  X|C → Ω1  C → 0  that is  0 → OP1(1) → Ω1  X|C → OP1(−2) → 0  gives that h1(Ω1  X |C) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally, from the exact sequence  0 → Ω1  X(H + KX − C) → Ω1  X(H + KX) → Ω1  X|C(H + KX) → 0  using that (H + KX)C = 0, we get that  h1(Ω1  X(H + KX)) ≥ h1(Ω1  X|C(H + KX)) = h1(Ω1  X|C) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  16  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  This completes the proof under the assumption that TX(1) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose now that X is a Del Pezzo surface of degree 5 and H = −2KX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Setting k = 1 in Lemma  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, we have that d = 4(g − 1) and, in order to verify that TX(1) is an Ulrich vector bundle, we need to  check that H0(TX) = H2(TX(−1)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The first vanishing is well known.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As for the second, we first  observe that for i < 2 we have  hi(TX(−1)) = h2−i(Ω1  X(H + KX)) = h2−i(Ω1  X(−KX)) = 0  by Bott vanishing [T, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore h2(TX(−1)) = χ(TX(−1)) = d − 4(g − 1) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally, as  X does not contain lines in the embedding given by H = −2KX, we have that TX(1) is very ample by  [LS, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1]  □  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Properties of complete intersections  We collect some properties inherited by the complete intersections Xi of X (as in Notation 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1),  when TX(k) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then q(X) = q(Xi) for  2 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By Kodaira vanishing we have that H1(OXi+1(−1)) = H2(OXi+1(−1)) = 0 as long as 2 ≤ i ≤  n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then the exact sequences  0 → OXi+1(−1) → OXi+1 → OXi → 0  imply that h1(OXi+1) = h1(OXi) for every 2 ≤ i ≤ n − 1, hence q(X) = q(Xi) for 2 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that k ≤ n − 2  and that TX(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Hi(OXi) = 0 for all i such that max{1, k + 1} ≤ i ≤ n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that max{1, k + 1} ≤ i ≤ n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since TX|Xi(k) is Ulrich, it follows by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(iv)  that Hi(TX |Xi(k + m)) = 0 for all m ≥ −i, hence Hi(TX |Xi(−1)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the exact sequence  0 → TXi(−1) → TX|Xi(−1) → O⊕(n−i)  Xi  → 0  implies that Hi(OXi) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that k ≤ n − 1  and that TX(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that Hi(OX) = 0 for all i ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Hi(OXj) = 0 for all i ≥ 1 and  for all j such that max{1, k + 1} ≤ j ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that i ≥ 1 and max{1, k + 1} ≤ j ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We prove the lemma by induction on n − j ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  If n − j = 0 then Xj = Xn = X and Hi(OX) = 0 for all i ≥ 1 just by our assumption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Next suppose that n − j ≥ 1, so that max{1, k + 1} ≤ j ≤ n − 1, hence, in particular k ≤ n − 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Consider the exact sequence  0 → OXj+1(−1) → OXj+1 → OXj → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  If j = i, we have that Hj(OXj) = 0 by Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, we have by induction that Hi(OXj+1) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now Hi+1(OXj+1(−1)) = 0 by Kodaira vanishing if i+1 < j+1 and by dimension reasons if i+1 > j+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus Hi(OXj) = 0 if i ̸= j and we are done.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We now collect some properties of the Xi’s that hold when TX(1) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that n ≥ 2 and  that TX(1) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then:  (i) H1(OXi) = 0 for 2 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) H2(OXi) = 0 for 1 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) H1(OXi(1)) = 0 for 1 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) H2(OXi(1)) = 0 for 1 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) h0(OXi(1)) = d − g + i for 1 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (vi) d ≥ n + 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  17  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have Hi(OX) = 0 for i ≥ 1 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now (i) follows by Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and (ii) follows  by Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (iii) observe that, if i = 1 we have that X1 = C and TX(1)|C is an Ulrich vector  bundle on C by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(ix), hence H1(TX |C) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then the exact sequence  0 → TC → TX|C → OC(1)⊕(n−1) → 0  shows that H1(OC(1)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If i ≥ 2, since H1(OXi) = 0 by (i), the exact sequences  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  0 → OXi → OXi(1) → OXi−1(1) → 0  imply by induction that H1(OXi(1)) = 0 and we get (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now (iv) is obvious for i = 1, while, for  i ≥ 2, the exact sequences (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) and (ii) show by induction that H2(OXi(1)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This proves (iv).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Note that (v) follows for i = 1 by Riemann-Roch and (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' For i ≥ 2, the exact sequences (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) and  (i) show by induction that h0(OXi(1)) = 1 + h0(OXi−1(1)) = d − g + i, that is (v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally, to see (vi),  observe that g − 1 = n−1  n+2d by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), hence g ≥ 2 and (v) gives that  3d  n+2 = h0(OC(1)) ≥ 3, so  that d ≥ n + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover, if equality holds, we get that g = n and h0(OX(1)) = n + 2 by (v), hence  X ⊂ PH0(H) = Pn+1 is a hypersurface of degree n + 2, so that KX = 0, contradicting Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Hence (vi) is proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' TX(k) Ulrich and special varieties in adjunction theory  In this section we exclude some special varieties frequently arising in adjunction theory, under the  hypothesis that TX(k) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The cases (X, H) = (Pn, OPn(1)), (Qn, OQn(1)) have  been already treated in Lemmas 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We start by recalling the following (see [BS, I]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Definition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let E be an effective divisor on (X, H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The divisor E is called exceptional  (i) of type 1 if (E, H|E) ∼= (Pn−1, OPn−1(1)) and NE/X ∼= OPn−1(−1),  (ii) of type 2 if (E, H|E) ∼= (Pn−1, OPn−1(1)) and NE/X ∼= OPn−1(−2),  (iii) of type 3 if (E, H|E) ∼= (Qn−1, OQn−1(1)) and NE/X ∼= OQn−1(−1),  (iv) of type 4 if (E, H|E) is a linear Pn−2-bundle over a smooth curve B and (NE/X)|F ∼= OPn−2(−1),  where F is a fiber of the structure morphism E → B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Often these exceptional divisors will not be present under the condition that TX(k) is Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see  this we first prove  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let W be a variety of dimension s ≥ 1 and let OW (1) be a very ample line bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then  Ω1  W(1) is not globally generated if:  (i) (W, OW (1)) ∼= (Ps, OPs(1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) (W, OW (1)) is a (possibly singular) quadric hypersurface in Ps+1 and s ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) (W, OW (1)) is a smooth Del Pezzo variety, s ≥ 2 and (W, OW (1)) ̸∈ {(P2, OP2(3)), (Q2, OQ2(2)),  (P3, OP3(2))}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (i) follows from det(Ω1  Ps(1)) = OPs(−1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (ii), observe that the restricted Euler sequence  0 → Ω1  Ps+1|W (1) → H0(OW (1)) ⊗ OW → OW (1) → 0  implies that H0(Ω1  Ps+1|W(1)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the exact sequence  0 → OPs+1(−3) → OPs+1(−1) → OW (−1) → 0  implies that H1(OW (−1)) = 0 and the dual normal bundle sequence  0 → OW (−1) → Ω1  Ps+1|W(1) → Ω1  W(1) → 0  gives that H0(Ω1  W (1)) = 0, hence Ω1  W(1) is not globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Next, to see (iii), observe that,  from the classification of Del Pezzo varieties [IP, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] it follows, for the surface section W2, that  (W2, OW2(1)) ̸∈ {(P2, OP2(3)), (Q2, OQ2(2)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence, as is well known, W2, and hence W, contains a line  L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But now the surjection Ω1  W(1) → Ω1  L(1) = OP1(−1) gives that Ω1  W(1) is not globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Now  18  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that TX(k) is  an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have:  (i) If k ≥ 1 and n ≥ 2, then (X, H) does not contain any exceptional divisor of type 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) If k ≥ 2 and n ≥ 2, then (X, H) does not contain any exceptional divisor of type 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) If k ≥ 2 and n ≥ 3, then (X, H) does not contain any exceptional divisors of types 3 or 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let E be an exceptional divisor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It follows from Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6 that Ω1  E(KX |E + (n + 1 − k)H|E) is  globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now  Ω1  E(KX |E + (n + 1 − k)H|E) ∼=  \uf8f1  \uf8f4  \uf8f2  \uf8f4  \uf8f3  Ω1  Pn−1(2 − k)  if E is of type 1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Ω1  Pn−1(3 − k)  if E is of type 2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Ω1  Qn−1(3 − k)  if E is of type 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Further, when E is of type 4, let F be a fiber of the structure morphism of E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Again it follows from  Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6 that Ω1  F (KX |F + (n + 1 − k)H|F ) ∼= Ω1  Pn−2(3 − k) is globally generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently, we  draw the conclusions from Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We now recall  Definition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We say that (X, H) is a linear Pk-bundle over a smooth variety B if (X, H) ∼=  (P(F), OP(F)(1)), where F is a very ample vector bundle on B of rank k + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We say that (X, H) as above is a scroll (respectively a quadric fibration;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' respectively a Del Pezzo  fibration) over a normal variety Y of dimension m if there exists a surjective morphism with connected  fibers φ : X → Y such that KX +(n−m+1)H = φ∗L (respectively KX +(n−m)H = φ∗L;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' respectively  KX + (n − m − 1)H = φ∗L), with L ample on Y .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We now use the fibration to exclude several varieties as above, when TX(k) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that TX(k) is  an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let f : X → B be a fibration onto a normal variety B of dimension m ≥ 1,  with general fiber F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then:  (i) If m ≤ min{n − 1, k + 1}, then (F, H|F ) ̸= (Pn−m, OPn−m(1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) If m ≤ min{n − 2, k}, then (F, H|F) ̸= (Qn−m, OQn−m(1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) if m ≤ min{n − 2, k − 1}, then (F, H|F) is not a Del Pezzo variety, unless (F, H|F) ∈  {(P2, OP2(3)), (Q2, OQ2(2)), (P3, OP3(2))}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have that  Ω1  F(KF + (n + 1 − k)H|F) ∼=  \uf8f1  \uf8f4  \uf8f2  \uf8f4  \uf8f3  Ω1  Pn−m(m − k)  if (F, H|F) = (Pn−m, OPn−m(1));' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Ω1  Qn−m(m − k + 1)  if (F, H|F) = (Qn−m, OQn−m(1));' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Ω1  F(m − k + 2)  if (F, H|F) is a Del Pezzo variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now Ω1  F(KF + (n + 1 − k)H|F ) is globally generated by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence, Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2 gives that, in  each of the three cases, the inequality in m, n, k is not satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We get a very useful consequence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(k) is an Ulrich  vector bundle, then KX +(n−1)H is nef and H0(KX +(n−1)H) ̸= 0, unless (X, H, k) = (P2, OP2(2), 0)  (the latter case actually occurs, see Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Recall that H0(KX + (n − 1)H) ̸= 0 if and only if KX + (n − 1)H is nef by [BS, Cor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now if KX + (n − 1)H is not nef, it follows by [BS, Prop.’s 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3 and 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4] that (X, H) is either  (Pn, OPn(1)), (Qn, OQn(1)), a linear Pn−1-bundle over a smooth curve or (P2, OP2(2)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The first three  cases are excluded by Lemmas 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5 and 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5(i), while in the fourth case we have g = 0, hence k = 0  by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We can now prove Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  19  Proof of Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The assert is clear if either (X, H) = (P1, OP1(3)) or (P2, OP2(2)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Vice versa  assume that TX is Ulrich for H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n = 1, since TX = −KX is globally generated by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(vi),  we have that X is either P1 or an elliptic curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the latter is excluded by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), while in  the former case TX = OP1(2) Ulrich implies that H = OP1(3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now assume that n ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then Lemma  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6 gives that either (X, H) = (P2, OP2(2)), or KX + (n − 1)H is nef, leading, by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii), to the  contradiction  0 ≤ (KX + (n − 1)H)Hn−1 = − 2d  n + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  The following result will also be useful.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that k ≥ 1 and  that TX(k) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that X ∼= P(F) is a projective bundle over a normal  projective variety B of dimension 1 ≤ m ≤ n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then B is smooth and F is simple.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In particular, if  m = 1, then q(X) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let π : X ∼= P(F) → B be the structure morphism and let ξ be the tautological bundle of  P(F).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By twisting F with a sufficiently ample line bundle we can assume that ξ is ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then [BS,  Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] implies that B is smooth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since H0(TX) = 0, the cohomology of the exact sequence  0 → TX/B → TX → π∗TB → 0  gives that H0(TX/B) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now the cohomology of the exact sequence  0 → OX → π∗F∗ ⊗ ξ → TX/B → 0  implies that  h0(F ⊗ F∗) = h0(π∗F∗ ⊗ ξ) = h0(OX) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now if m = 1 and q(X) = 0 we have that B ∼= P1, hence F cannot be simple since rk F = n ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Next we prove three results for k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  For the first one, in order to apply the results of T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fujita in [F1], we give the following definition,  that coincides with the one in [F1] when B is smooth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Definition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let f : X → B be a fibration over a curve, L an ample line bundle on X such that on  the general fiber F we have that KF = −(n − 2)L|F .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We say that f is minimal if there is a line bundle  L on B such that KX + (n − 2)L = f ∗L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then we have  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that k ≥ 2 and  that k = 2 if n = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover assume that TX(k) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then:  (i) (X, H) is not a Del Pezzo fibration over a smooth curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) If n = 4 and KX + 2H is ample, then (X, KX + 2H) is not a minimal (P3, OP3(2))-fibration  over a smooth curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' For the sake of contradiction, let L be H in case (i) and KX + 2H in case (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume that we  have a fibration f : X → B over a smooth curve B such that (X, L) is a Del Pezzo fibration in case (i)  (see Definition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) and (X, L) is a minimal (P3, OP3(2))-fibration in case (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that f is minimal  also in case (i) by Definition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Let F be a general fiber of f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In case (i) we have that F is a smooth variety of dimension n − 1 and  KF = KX|F = −(n − 2)L|F, hence F is a Del Pezzo variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since L = H, Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5 implies that  (F, H|F) = (P3, OP3(2)), hence n = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus (F, L|F ) is the same in both cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We now claim that every fiber of f is irreducible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Indeed, if not, let F0 be a reducible fiber.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since  F0 is connected, it must be singular, hence we can apply [F1, Table (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='20)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It follows that we are in  case (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='17) of [F1, Table (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='20)], the degree of F0 is 8 and, if D is an irreducible component of F0, then  (D, L|D) is a scroll over P1 and KX |D = −2L|D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Denoting a fiber of the structure morphism D → P1  by F ′ ∼= P2, we obtain L|F ′ = OP2(1) and KX|F ′ = −2L|F ′ = OP2(−2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Set H|F ′ = OP2(a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In case (ii)  we have that  OP2(1) = L|F ′ = (KX + 2H)|F ′ = OP2(−2 + 2a)  20  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In case (i) we have that L = H and a = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But now Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6 gives that Ω1  P2(KX |F ′ +  3H|F ′) ∼= Ω1  P2(1) is globally generated, contradicting Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus every fiber of f is irreducible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now [F1, (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8)] implies that every fiber of f is P3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since B is a smooth curve, it follows, as is well  known, that X is a projective bundle over B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand, since n = 4, we have that k = 2 and  q(X) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii), contradicting Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that KX + 2H is  ample and that TX(2) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then (X, KX + 2H) is not a quadric fibration over  a smooth curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that (X, KX + 2H) is a quadric fibration π : X → B over a smooth curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since  χ(OX) = 1 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii), it follows from [Lan, Sect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (8)] that B ∼= P1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Moreover, [Lan,  Sect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] gives that if π∗(KX + 2H) ∼=  4�  i=0  OP1(ai) and e = �4  i=0 ai, then there is b ∈ Z such that  (KX + 2H)4 = 2e − b  by [Lan, Sect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (3)] and  Ki  X(KX + 2H)4−i = (−3)i2e + (−3)i−1(−4i + 2ie + (3 − 2i)b) for 1 ≤ i ≤ 4  by [Lan, Sect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1, eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (4)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Solving these five equations we obtain  KXH3 = 4e − 28b − 104 and d = H4 = 16b + 64  and therefore Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii) gives  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  13d = 48(2 + e).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Since TX(2) is Ulrich we have that H4(TX(−2)) = 0 and the exact sequence  0 → TX/P1(−2) → TX(−2) → (π∗TP1)(−2) → 0  implies that H4((π∗TP1)(−2)) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence, by Serre duality  0 = h4((π∗TP1)(−2)) = h0((π∗OP1(−2))(KX+2H)) = h0(π∗(KX+2H)⊗OP1(−2)) =  4  �  i=0  h0(OP1(ai−2))  and therefore ai ≤ 1 for 0 ≤ i ≤ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But then e ≤ 5 and (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) gives that 1 ≤ e + 2 ≤ 7 is divisible by 13,  a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose that KX + 2H is  ample and that TX(2) is an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then (X, KX + 2H) is not a linear P2-bundle over  a smooth surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Assume by contradiction that we have a P2-bundle structure π : X ∼= P(F) → B onto a smooth  surface B, with KX + 2H = ξ, the tautological bundle, where F is a rank 3 vector bundle on B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then  H = aξ − π∗M for some a ∈ Z and M ∈ Pic(B), so that  ξ = KX + 2H = (2a − 3)ξ + π∗(KB + c1(F) − 2M)  giving a = 2 and 2M = KB + c1(F), thus  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  H ≡ 2ξ − 1  2π∗(KB + c1(F)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We will also use Grothendieck’s relation  3�  j=0  (−1)jξ3−jπ∗cj(F) = 0, that is  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3)  ξ3 = ξ2π∗c1(F) − ξπ∗c2(F).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Since ξ2f = 1 for every fiber f of π, we get from (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) that  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4)  ξ3π∗c1(F) = c1(F)2, ξ3π∗KB = KBc1(F) and ξ4 = c1(F)2 − c2(F).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We first collect some invariants of X and B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have:  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  21  (i) KXH3 = − 2  3d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) χ(OX) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) χ(OX(H)) = 2 + χ(OS) − d  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) h0(KX + 2H) = χ(OS) − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) χ(OB) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (i) is obtained by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii) gives that Hi(OX) = 0 for i ≥ 1, hence  Hi(OB) = 0 for i ≥ 1, giving (ii) and (v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Next, to see (iii), consider the exact sequences  0 → OXi → OXi(H) → OXi−1(H) → 0  for i = 4, 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' They give χ(OX(H)) = 1+χ(OX3(H)) = 2+χ(OS(H)) and (iii) follows by Riemann-Roch  since H2  |S = d and H|SKS = (KX + 2H)H3 = 4  3d by (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (iv), observe that, since Rjπ∗(−ξ) = 0  for every j ≥ 0, we have that Hi(KX + H) = Hi(−ξ + π∗(KB + c1(F) − M)) = 0 for every i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence  the exact sequence  0 → KX + H → KX + 2H → KX3 + H|X3 → 0  implies that  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5)  h0(KX + 2H) = h0(KX3 + H|X3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now we have q(S) = 0 by Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and Hi(KX3) = 0 for i = 0, 1 by Serre duality and Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Hence the exact sequence  0 → KX3 → KX3 + H|X3 → KS → 0  shows that  χ(OS) − 1 = pg(S) = h0(KS) = h0(KX3 + H|X3)  and we get (iv) by (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We continue the proof of the lemma.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Next, we collect some relations among the invariants related to ξ, KB and the Chern classes of F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The following identities hold:  (i) d − 6c1(F)2 + 16c2(F) − 6K2  B + 4KBc1(F) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) KBc1(F) − 8 + 2χ(OS) − c1(F)2 + 2c2(F) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) K2  B − 1 + c1(F)2 − 3c2(F) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) 3K2  B + c1(F)2 − 2c2(F) − 30 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (v) 4 − KBc1(F) + 9  4K2  B + 7  4c1(F)2 − 5c2(F) − χ(OS) + 1  6d = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have by (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) and (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) that  d = H4 = (2ξ − 1  2π∗(KB + c1(F)))4 = 16(c1(F)2 − c2(F)) + 6K2  B − 4KBc1(F) − 10c1(F)2  that is (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To see (ii) observe that, since π∗ξ = F and Rjπ∗ξ = 0 for j > 0 we have Hi(F) = Hi(ξ) =  Hi(KX + 2H) = 0 for i > 0 by Kodaira vanishing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, by Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12(iv), (v) and Riemann-Roch we  get  χ(OS) − 1 = h0(KX + 2H) = h0(ξ) = h0(F) = χ(F) = 3 − 1  2KBc1(F) + 1  2c1(F)2 − c2(F)  that is (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Next, consider the exact sequences  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6)  0 → TX/B → TX → π∗TB → 0  and  0 → OX → π∗F∗(ξ) → TX/B → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Since TX(2H) is Ulrich, we have that χ(TX) = 0, hence, using Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12(ii) we get  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7)  χ(TB) = χ(π∗TB) = −χ(TX/B) = −χ(π∗F∗(ξ)) + 1 = −χ(F ⊗ F∗) + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  On the other hand, by Riemann-Roch and Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12(v), χ(TB) = 2K2  B − 10 and χ(F ⊗ F∗) =  9 + 2c1(F)2 − 6c2(F).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Replacing in (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7) gives (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  22  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Finally, to see (iv), we first compute c1(S2(F)) = 4c1(F) and c2(S2(F)) = 5c1(F)2 + 5c2(F), so that  c1(S2(F)(−M)) = −3KB + c1(F), c2(S2(F)(−M)) = 15  4 K2  B − 5  2KBc1(F) − 5  4c1(F)2 + 5c2(F).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now Riemann-Roch gives  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8)  χ(S2(F)(−M)) = 6 − KBc1(F) + 9  4K2  B + 7  4c1(F)2 − 5c2(F).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  On the other hand, χ(S2(F)(−M)) = χ(2ξ − π∗M) = χ(OX(H)) = 2 + χ(OS) − d  6 by Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12(iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Using (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8) we get (v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We now conclude the proof of the lemma.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Solving the five equations in Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='13 we get  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9)  K2  B = − 7  48d + 7 and KBc1(F) = − 5  48d + 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In particular d ≥ 48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand, using Claim 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='12(i), we get  µ(TX) = −KXH3  4  = 1  6d  and, using (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  µ(π∗TB) = c1(π∗TB)H3  2  = −π∗KB  �  2ξ − 1  2π∗(KB + c1(F))  �3  2  = −8ξ3π∗KB − 6ξ2π∗(K2  B + KBc1(F))  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) and (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9) give  µ(π∗TB) = −KBc1(F) + 3K2  B = −1  3d + 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Since TX is semistable by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(v), we deduce by (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) that  1  6d ≤ −1  3d + 12  that is d ≤ 24, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' TX(1) Ulrich in any dimension  We study the case k = 1 in any dimension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We start analyzing the properties of the curve section C  and of the surface section S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Lemma 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(1) is an Ulrich  vector bundle, then d ≥ 9 except, possibly, when d = 8, g = 5, n = 4 and h0(OC(1)) = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' By Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) we know that g ≥ 2 and that  (9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  (n − 1)d = (n + 2)(g − 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  By Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4(v) we have d − g + 1 = h0(OC(1)) ≥ 3, hence g ≤ d − 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Also, if equality holds,  then h0(OC(1)) = 3, so that d − 2 = g =  �d−1  2  �  , thus d = 3 and g = 1, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore  2 ≤ g ≤ d − 3, hence d ≥ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But if d ≤ 8 the only possibility given by (9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) is d = 8, g = 5, n = 4 and  h0(OC(1)) = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let X ⊆ PN be a smooth irreducible variety of dimension n ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If TX(1) is an Ulrich  vector bundle we have:  (i) KSH|S = n−4  n+2d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (ii) q(S) = pg(S) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iii) K2  S = − 3(n−2)  2(n+2)d − n−12  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (iv) S is rational.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  23  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (i) follows by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii), while (ii) follows by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii), Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 and Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Note now that the equation in Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(vii) can be rewritten as  3(n − 2)d + 2(n + 2)K2  S + (n + 2)(n − 12) = 0  giving (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Finally assume that S is not ruled, so that κ(S) ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6 gives that  KS + H|S = (KX + (n − 1)H)|S is nef, hence KS(KS + H|S) ≥ 0, that is K2  S ≥ −KSH|S = − n−4  n+2d by  (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then (iii) gives  −3(n − 2)  2(n + 2)d − n − 12  2  = K2  S ≥ −n − 4  n + 2d  so that  (n + 2)(d + n − 12) ≤ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Since n ≥ 3 it follows that d ≤ 9, and using Lemma 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1 we deduce that either d = 9, n = 3 or  d = 8, g = 5, n = 4 and h0(OC(1)) = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In the first case we get a contraction by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), while in  the second case d + n − 12 = 0, hence K2  S = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As C ⊂ P3 we deduce that S ⊂ P4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But this contradicts  the well-known formula for the invariants of a surface in P4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore S is ruled, hence rational by (ii)  and (iv) is proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  We are now ready to prove Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof of Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If n = 1 we know by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i) that TX(1) is not an Ulrich vector bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' If  n = 2 this is Theorem 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Suppose next that n ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note that H0(TX) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(iii), hence  X is neither Pn nor Qn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also q(X) = 0 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have that (X, H) is not:  (1) A projective bundle over a smooth curve by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (2) A Del Pezzo manifold by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i), since otherwise g = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (3) A hyperquadric fibration over a smooth curve (in the sense of [I]), by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (4) A linear Pn−2-bundle over a smooth surface, by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Also observe that X does not contain any exceptional divisor of type 1 by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence (X, H)  is isomorphic to its reduction (X′, H′) (see [I, (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11)]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It follows by [I, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7)] that KX +(n−2)H  is nef.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hence S is minimal and rational by Lemma 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(iv), a contradiction since a minimal rational  surface does not have nef canonical bundle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus the case n ≥ 3 does not occur and the theorem is  proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' TX(2) Ulrich in any dimension  We prove Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' It follows by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2(iii) that H0(TX) = 0, hence X is neither Pn nor Qn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Note  that Hi(OX) = 0 for i ≥ 1 by Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(iii) and KX is not nef, since Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) gives that  KXHn−1 = n(3−n)  n+2 d < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We divide the proof according to the value of τ(X, H) (see (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We will also use the notions of  first and second reduction of (X, H), as defined in [BS, Defs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3 and 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case A: τ(X, H) ≥ n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This case does not occur since Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6(iii) implies that τ(X, H) ≤ n −  2n  n+1 < n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case B: n − 2 ≤ τ(X, H) < n − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then KX +(n−1)H is ample, hence the first reduction exists and is isomorphic to (X, H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Therefore  [BS, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4] implies that τ(X, H) = n − 2 and then [BS, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3] gives that (X, H) is one of  the following:  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) a Mukai variety,  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) a Del Pezzo fibration over a smooth curve,  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) a quadric fibration over a normal surface,  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) a scroll over a normal threefold,  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5) (X, H) contains an exceptional divisor of type 2, 3, or 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  24  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  Now, the case (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) is ruled out by Corollary 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Case (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) is excluded for n = 4 by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9(i)  and for n ≥ 5 by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5(iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also the cases (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) and (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) are ruled out by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5(ii) and  (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Finally the case (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5) is excluded by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) and (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus also Case B does not occur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case C: τ(X, H) < n − 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then the first and second reductions exist and are both isomorphic to (X, H), since KX + (n − 2)H  is ample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We first claim that KX3 is not nef.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In fact, assume that KX3 is nef.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the one hand, χ(OX3) = 1  by Lemma 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On the other hand, 3c2(X3) − c1(X3)2 is pseff by [M, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1], hence 3c2(X3)KX3 ≥  K3  X3 ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But then Riemann-Roch gives χ(OX3) = − 1  24c2(X3)KX3 ≤ 0, a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Hence KX3 is not nef and [BS, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] gives the following cases:  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) n = 5 and (X, KX + 3H) is a linear P4-bundle over a smooth curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) n = 4 and (X, KX + 2H) is a Del Pezzo.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) n = 4 and (X, KX + 2H) is a quadric fibration over a smooth curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) n = 4 and (X, KX + 2H) is a scroll over a normal surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5) n = 4 and (X, H) contains an exceptional divisor of type 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) n = 4 and (X, KX + 2H) is a (P3, OP3(2))-fibration over a curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In case (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) we have a contradiction by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In case (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) we have 4KX + 6H = 0, hence  4KXH3+6H4 = 0 and Lemma 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii) gives the contradiction d = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Cases (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) and (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5) do not occur  by Lemmas 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='10 and 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In Case (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) we observe that the fibration is obtained in [F2, (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)] by  contracting an extremal ray, hence it is minimal (see Definition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8) and the image is a normal, hence  smooth, curve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus this case is excluded by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='9(ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Hence we are left with case (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have a surjective morphism π : X → B and denoting by F a  general fiber, we have (F, (KX + 2H)|F ) ∼= (P2, OP2(1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Now all fibers of π are 2-dimensional by [BS,  Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1], hence we get by [BS, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1] that B is a smooth surface and (X, KX + 2H) is a  linear P2-bundle over B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But this case is excluded by Lemma 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This concludes the proof of the theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  References  [A]  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Ambro.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Ladders on Fano varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Algebraic geometry, 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' (New York) 94 (1999), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1,  1126-1135.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 7  [Be1]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Beauville.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' An introduction to Ulrich bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4 (2018), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 26-36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 3  [Be2]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Beauville.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Complex algebraic surfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' London Mathematical Society Lecture Note Series, 68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Cambridge  University Press, Cambridge, 1983.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' iv+132 pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 14  [BC]  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Bauer, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Catanese.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On rigid compact complex surfaces and manifolds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Adv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 333 (2018), 620-669.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 14  [BMQ]  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Bogomolov, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' McQuillan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Rational curves on foliated varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Foliation theory in algebraic geometry,  21–51, Simons Symp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', Springer, Cham, 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5  [BMPT]  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Benedetti, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Montero, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Prieto Monta˜nez, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Troncoso.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Projective manifolds whose tangent bundle is  Ulrich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Preprint 2021, arXiv:2108.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='13944.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 6  [Bo]  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Bogomolov.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Unstable vector bundles and curves on surfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Proceedings of the International Congress  of Mathematicians (Helsinki, 1978), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 517-524, Acad.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fennica, Helsinki, 1980.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4  [BS]  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Beltrametti, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Sommese.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The adjunction theory of complex projective varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' De Gruyter Exposi-  tions in Mathematics, 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Walter de Gruyter & Co.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', Berlin, 1995.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5, 17, 18, 19, 23, 24  [C1]  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Casnati.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Special Ulrich bundles on non-special surfaces with pg = q = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Internat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 28 (2017), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  8, 1750061, 18 pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 13  [C2]  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Casnati.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Tangent, cotangent, normal and conormal bundles are almost never instanton bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Preprint  2022, in preparation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1  [CH]  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Casanellas, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hartshorne.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Stable Ulrich bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' With an appendix by F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Geiss, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='-O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Schreyer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Internat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 23 (2012), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 8, 1250083, 50 pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 5  [CMRPL] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Costa, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Mir´o-Roig, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Pons-Llopis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Ulrich bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' De Gruyter Studies in Mathematics, 77, De Gruyter  2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1  [CP]  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Campana, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' P˘aun.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Foliations with positive slopes and birational stability of orbifold cotangent bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Publ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Inst.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hautes ´Etudes Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 129 (2019), 1-49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5  [DR]  S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Di Rocco.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' k-very ample line bundles on del Pezzo surfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Nachr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 179 (1996), 47-56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 15  [ES]  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Eisenbud, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='-O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Schreyer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Resultants and Chow forms via exterior syzygies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Amer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 16 (2003),  no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 537-579.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 3  [F1]  T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fujita.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On del Pezzo fibrations over curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Osaka J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 27 (1990), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 229-245.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 19, 20  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  25  [F2]  T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fujita.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On Kodaira energy and adjoint reduction of polarized manifolds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Manuscripta Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 76 (1992), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  1, 59?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 24  [FL1]  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fulger, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Lehmann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Morphisms and faces of pseudo-effective cones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Lond.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 112 (2016),  no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4, 651-676.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5  [FL2]  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fulger, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Lehmann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Positive cones of dual cycle classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Algebr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Geom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4 (2017), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1-28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5  [GL]  L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Ghidelli, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Lacini.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Logarithmic bounds on Fujita’s conjecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Preprint 2021, arXiv:2107.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='11705.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 8  [Ha1]  R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Hartshorne.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Algebraic geometry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Graduate Texts in Mathematics 52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Springer-Verlag, New York-Heidelberg,  1977.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' On the classification of algebraic space curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Vector bundles and differential equations (Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Conf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', Nice, 1979), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 83-112, Progr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', 7, Birkh¨auser, Boston, Mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', 1980 12  [Ho]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' H¨oring.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On a conjecture of Beltrametti and Sommese.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Algebraic Geom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 21 (2012), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4, 721-751.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Generalized adjunction and applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Cambridge Philos.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' 17, 23  [IP]  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Prokhorov.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Fano varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In: Algebraic geometry, V, 1-247, Encyclopaedia Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' On effective non-vanishing and base-point-freeness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Kodaira’s issue.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Asian J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Hilbert curves of quadric fibrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Internat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Lopez.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On varieties with Ulrich twisted normal bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Preprint 2022, arXiv:2205:06602.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Positivity in algebraic geometry, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Ergebnisse der Mathematik und ihrer Grenzgebiete, 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Folge  48, Springer-Verlag, Berlin, 2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' A geometrical view of Ulrich vector bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Preprint 2021, arXiv:2105.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='05979.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' To  appear on Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Res.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' IMRN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5, 16  [M]  Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' The Chern classes and Kodaira dimension of a minimal variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Pure Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', 10, North-Holland, Amsterdam, 1987.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Sumihiro.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' On Hartshorne’s conjecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Kyoto Univ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
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+page_content=' Bott vanishing for algebraic surfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Trans.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Amer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 373 (2020), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 5, 3609-3626.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 15, 16  [W]  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Wahl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' A cohomological characterization of Pn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Invent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 72 (1983), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 315-322.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 4  Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Some numerical lemmas  Lemma A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' c1, c2, c3, c4) ∈ Z5 be such that c1 ≥ c2 ≥ c3 ≥ c4 ≥ 0, a ≥ c1 + c2 + 3 and  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1)  a2 − 6a + 4 = c2  1 + c2  2 + c2  3 + c2  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' c1, c2, c3, c4) ∈ {(6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 0, 0, 0), (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1), (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 1, 1, 0), (9;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 2)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2)  a − 3 ≥ c1 + c2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Now, (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) and (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) imply that (a − 3)2 − 5 = c2  1 + c2  2 + c2  3 + c2  4 ≥ (c1 + c2)2 − 5, that is  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3)  c2  3 + c2  4 ≥ 2c1c2 − 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  But 2c2  3 ≥ c2  3 + c2  4 and 2c1c2 ≥ 2c2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently, we get  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4)  5 ≥ 2(c2 − c3)(c2 + c3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus, one of the following should happen:  (α) c2 = c3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (β) c2 = c3 + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  First assume that case (β) holds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) yields 2c3 ≤ 1 which gives c3 = 0, c2 = 2 and hence c4 = o.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' The (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) gives  (a + c1 − 3)(a − c1 − 3) = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus we have one of the following possibilities  a + c1 = 4, a − c1 = 9, or a + c1 = 5, a − c1 = 6, or a + c1 = 6, a − c1 = 5, or a + c1 = 9, a − c1 = 4  but none of them have integer solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Assume now that case (α) holds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Set c2 = c3 = c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' From (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3), we obtain c2 + c2  4 ≥ 2c1c − 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since c ≥ c4, we get  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='5)  5 ≥ 2c(c1 − c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  The above implies one of the following happens:  26  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' LOPEZ, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' RAYCHAUDHURY  (α1) c2 = c3 = c4 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (α2) c1 = c2 = c3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (α3) c2 = c3 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This case has two sub-cases, namely c1 = 2, 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (α4) c2 = c3 = 1, c1 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose we are in case (α1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) gives (a − 3)2 − 5 = c2  1, so that (a + c1 − 3)(a − c1 − 3) = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  In this case, either  a + c1 = 4, a − c1 = 8, giving the contradiction c1 = −2, or a + c1 = 8, a − c1 = 4, giving a = 6, c1 = 2  and the solution (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 0, 0, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose we are in case (α2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Using (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) we conclude  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6)  5 ≥ (c − c4)(c + c4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  As before, we obtain the following cases:  (α21) c = c1 = c2 = c3 = c4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (α22) c = c4 + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  (α23) c = c4 + 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We first deal with (α21).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case, from (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1), we obtain  (a + 2c − 3)(a − 2c − 3) = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus, we have either a + 2c = 4, a − 2c = 8, giving the contradiction c = −1, or a + 2c = 8, a − 2c = 4,  giving the solution (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We now deal with (α22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  From (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='6) we obtain c + c4 − 2 ≤ 5, hence c4 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus (c, c4) ∈  {(3, 2), (2, 1), (1, 0)} and using (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) we see that it has no integer solutions except in the first case,  giving the solution (9;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We now deal with (α23).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' As before, in this case we have c4 ≤ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' This implies c = 2, c4 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' But  then (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) does not have any integer solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This concludes case (α2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose we are in case (α3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  We know that (c1, c2, c3, c4) ∈ {(1, 1, 1, 1), (2, 1, 1, 0), (3, 1, 1, 1), (3, 1, 1, 0)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Using (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) we see that  we have no integer solutions except in the last case, giving (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 1, 1, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Suppose we are in case (α4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then (c1, c2, c3, c4) ∈ {(3, 2, 2, 2), (3;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 1), (3;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 0)} and (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) has no integer solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  This concludes case (α) and the proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Lemma A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Let z = (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' b1, b2, b3, b4, b5, b6) ∈ Z7 with b1 ≥ b2 ≥ b3 ≥ b4 ≥ b5 ≥ b6 satisfying the  following  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='7)  a2 −  6  �  i=1  b2  i = 10,  3a −  6  �  i=1  bi = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Then z ∈ {(4;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 1, 1, 1, 1, 1, 1), (5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 2, 1, 1, 1), (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 2, 2, 2, 2, 1), (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 2, 2, 2), (8;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 3, 3, 3)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We first use the Cauchy-Scwartz’s inequality (�6  i=1 bi)2 ≤ 6(�6  i=1 b2  i ) to obtain (a2−12a+32) ≤  0 whence 4 ≤ a ≤ 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We further observe that  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='8)  6  �  i=1  (b2  i − bi) = a2 − 3a − 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Also, (b2  i − bi) ≥ 0 for all i ≥ 1, and b1 > 0 as 3a − 6 > 0 for a ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 1: a = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have �6  i=1(b2  i − bi) = 0 whence |bi| ≤ 1 for all i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Since �6  i=1 bi = 6, we have bi = 1  for all i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 2: a = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have �6  i=1(b2  i − bi) = 6 whence |bi| ≤ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, �6  i=1 b2  i = 15 and �6  i=1 bi = 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b1 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case �6  i=2(b2  i − bi) = 0 whence |bi| ≤ 1 for all i ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently  �6  i=1 bi ≤ 8 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b1 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case we must have b1 = b2 = b3 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=4(b2  i − bi) = 0  whence |bi| ≤ 1 for all i ≥ 4 whence the only solution is z = (5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 2, 2, 2, 1, 1, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  ON VARIETIES WITH ULRICH TWISTED TANGENT BUNDLE  27  Case 3: a = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have �6  i=1(b2  i − bi) = 14 whence |bi| ≤ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also �6  i=1 b2  i = 26 and �6  i=1 bi = 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b1 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=2(b2  i − bi) = 2 whence |bi| ≤ 2 for i ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently b2 = b3 = b4 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  But then �6  i=1 b2  i ≥ 28 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b1 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b2 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case �6  i=3(b2  i − bi) = 2 whence |bi| ≤ 2 for i ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently, b3 = b4 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Thus b5 + b6 = 2 and b2  5 + b2  6 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b2 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case we have the only solution z = (6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 2, 2, 2, 2, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b1 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case bi = 2 for all i whence �6  i=1 b2  i = 24 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 4: a = 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have �6  i=1(b2  i − bi) = 24 whence |bi| ≤ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, �6  i=1 b2  i = 39 and �6  i=1 bi = 15.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b1 = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=2(b2  i − bi) = 4 whence |bi| ≤ 2 for all i ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently bi = 2 for all  i, thus �6  i=1 b2  i = 45 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b1 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b2 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=3(b2  i − bi) = 0 whence |bi| ≤ 1 for all i ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=1 bi ≤ 12  which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b2 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b3 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=4(b2  i − bi) = 0 whence |bi| ≤ 1 for i ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=1 bi ≤ 13  which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b3 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then bi = 2 for all i ≥ 3 whence �6  i=1 b2  i = 41 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b2 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=1 bi ≤ 14 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b1 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then b2 = b3 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b4 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=5(b2  i − bi) = 0 whence |bi| ≤ 1 for i ≥ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=1 bi ≤ 14 which  is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b4 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then b4 = b5 = b6 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We get only one solution z = (7;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 2, 2, 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) b1 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=1 bi ≤ 12 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Case 5: a = 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' We have �6  i=1(b2  i − bi) = 36 whence |bi| ≤ 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Also, �6  i=1 b2  i = 54 and �6  i=1 bi = 18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b1 = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=2(b2  i − bi) = 6 whence |bi| ≤ 3 for i ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b2 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case �6  i=3(b2  i − bi) = 0 whence |bi| ≤ 1 for i ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=1 bi ≤ 13  which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b2 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case �6  i=1 bi ≤ 16 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b1 = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=2(b2  i − bi) = 16 whence |bi| ≤ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b2 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=3(b2  i − bi) = 4 whence |bi| ≤ 2 for i ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus �6  i=1 bi ≤ 17 which is a  contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b2 = 3 which implies b3 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=4(b2  i − bi) = 4 whence |bi| ≤ 2 for i ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently  �6  i=1 bi ≤ 17 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b2 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=1 bi ≤ 15 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b1 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b2 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1) b3 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=4(b2  i − bi) = 0 whence |bi| ≤ 1 for i ≥ 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=1 bi ≤ 15  which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b3 = 3 which implies b4 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Thus �6  i=5(b2  i −bi) = 0 whence |bi| ≤ 1 for i ≥ 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently  �6  i=1 bi ≤ 16 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b3 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=1 bi ≤ 16 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='2) b2 = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then b3 = b4 = b5 = 3 and b6 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Consequently �6  i=1 b2  i = 56 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='3) b2 ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' Then �6  i=1 bi ≤ 14 which is a contradiction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  Subcase 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='4) b1 ≤ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' In this case we have the only solution z = (8;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' 3, 3, 3, 3, 3, 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  □  Angelo Felice Lopez, Dipartimento di Matematica e Fisica, Universit`a di Roma Tre, Largo San Leonardo  Murialdo 1, 00146, Roma, Italy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' e-mail lopez@mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='uniroma3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='it  Debaditya Raychaudhury, Department of Mathematics, University of Toronto, Bahen Centre, 40 St.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='  George St.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=', Room 6290, Toronto, ON M5S 2E4, Canada.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content=' email: debaditya.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='raychaudhury@utoronto.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
+page_content='ca' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE1T4oBgHgl3EQfVgTd/content/2301.03104v1.pdf'}
diff --git a/BdE3T4oBgHgl3EQfUAoU/content/tmp_files/2301.04446v1.pdf.txt b/BdE3T4oBgHgl3EQfUAoU/content/tmp_files/2301.04446v1.pdf.txt
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+An Efficient Approach to the Online Multi-Agent Path Finding Problem
+by Using Sustainable Information
+1, 3Mingkai TANG, 1, 6Boyi LIU, 1, 4Yuanhang LI, 1, 2, 5Hongji LIU, 1, 2, 7Ming LIU, 1, 8Lujia WANG
+1The Hong Kong University of Science and Technology
+2The Hong Kong University of Science and Technology (Guangzhou)
+{3mtangag, 4yliog, 5hliucq}@connect.ust.hk, 6by.liu@ieee.org, {7eelium, 8eewanglj}@ust.hk
+Abstract
+Multi-agent path finding (MAPF) is the problem of mov-
+ing agents to the goal vertex without collision. In the on-
+line MAPF problem, new agents may be added to the envi-
+ronment at any time, and the current agents have no infor-
+mation about future agents. The inability of existing online
+methods to reuse previous planning contexts results in redun-
+dant computation and reduces algorithm efficiency. Hence,
+we propose a three-level approach to solve online MAPF uti-
+lizing sustainable information, which can decrease its redun-
+dant calculations. The high-level solver, the Sustainable Re-
+plan algorithm (SR), manages the planning context and sim-
+ulates the environment. The middle-level solver, the Sustain-
+able Conflict-Based Search algorithm (SCBS), builds a con-
+flict tree and maintains the planning context. The low-level
+solver, the Sustainable Reverse Safe Interval Path Planning
+algorithm (SRSIPP), is an efficient single-agent solver that
+uses previous planning context to reduce duplicate calcula-
+tions. Experiments show that our proposed method has sig-
+nificant improvement in terms of computational efficiency. In
+one of the test scenarios, our algorithm can be 1.48 times
+faster than SOTA on average under different agent number
+settings.
+1
+Introduction
+The multi-agent path finding problem (MAPF) is finding
+paths for a set of agents to move from their starting ver-
+tex to the goal vertex without collision. MAPF has a wide
+practical application, such as aircraft towing vehicles (Mor-
+ris et al. 2016), warehouse robots (Wurman, D’Andrea, and
+Mountz 2008), video games (Ma et al. 2017b) and urban
+road networks (Choudhury et al. 2022).
+For MAPF, most works assume that the environment can
+be fully captured before the system runs (Salzman and Stern
+2020; Stern 2019; Ma et al. 2017a). Under this assumption,
+the solution can be calculated in advance, and the agent only
+needs to take actions along the pre-calculated plan at run-
+time. These path finding problems are referred to as offline
+MAPF. However, in practice, the assumption is not always
+guaranteed. During the running of a system, new agents
+might appear in the system suddenly, and agents need to
+do replanning to fit the new situation. Recently, the online
+MAPF problem (ˇSvancara et al. 2019) was proposed. It is
+assumed that new agents may be added to the environment
+at any time, and the current agents have no information about
+Figure 1: An example of two online MAPF instances. In
+both instances, a1 appears A4 at time point 0 and needs to
+travel to D1. P1 and P2 are two paths with equal costs for
+a1. In the first instance, a2 appears in C1 at time point 1,
+and its goal is A2. In the second instance, a′
+2 appears in D2
+at time point 1, and its goal is C4.
+future agents. All agents in the environment need to do re-
+planning to fit the new situation.
+Online MAPF is a problem of great practical importance.
+For example, in a real-world warehouse system, the robot
+frequently enters and exits the work area due to factors
+such as charging or malfunction. Moreover, the time point
+at which the robot re-enters the work area is unpredictable.
+The agents in the warehouse need to adjust their path due to
+the appearance of a new agent.
+Optimally solving the offline MAPF problem is NP-hard
+(Yu and LaValle 2013; Ma et al. 2016). Compared with the
+offline MAPF, which can calculate the paths before the sys-
+tem runs, the online MAPF further needs to calculate high-
+quality paths for all agents in real-time when new agents
+appear. ˇSvancara et al. proposed several methods to solve
+the online MAPF problem. The Replan Single algorithm
+searches an optimal path for each new agent when they
+appear, while all paths of the old agents remain the same.
+The Replan Single Group algorithm jointly plans for all new
+agents appearing at the same time, and the new agents’ path
+plan cannot affect the old agents’ path plan. These two al-
+arXiv:2301.04446v1  [cs.MA]  11 Jan 2023
+
+P1
+α1
+α2
+P2
+α2
+α2
+α2
+α1gorithms can execute fast, but the solutions are not optimal.
+The Replan All algorithm replan for all agents without con-
+sidering existing path plans when new agents appear, and
+it can get high-quality solutions. However, each iteration of
+planning in the Replan All algorithm has a high computa-
+tional complexity when the number of agents becomes large.
+Considering reusing the information in previous planning
+iterations to reduce the running time, we propose an efficient
+algorithm. In this paper, we refer to this kind of information
+as sustainable information or planning context. Our method
+consists of three levels of algorithms. We name the high-
+level algorithm as the Sustainable Replan algorithm(SR). It
+simulates the environment and maintains the whole plan-
+ning context. The middle-level algorithm, the Sustainable
+Conflict-Based Search Algorithm (SCBS), is called by SR
+for searching the multi-agent path planning solution based
+on current information. SCBS uses the Sustainable Reverse
+Safe Interval Path Planning algorithm (SRSIPP), which is
+the low-level solver, for single-agent planning. Given that
+each planning iteration for a single agent has the same goal
+point, but different starting points, SRSIPP searches the path
+in the backward direction (from goal point to starting point)
+to reuse the previous planning information.
+The main contributions of this paper are as follows.
+1. We propose a three-level approach for reusing previous
+planning context to reduce the running time for the online
+MAPF.
+2. We prove the completeness and the snapshot optimality
+of our approaches.
+3. We performed detailed algorithm performance compar-
+ison experiments with SOTA. The average acceleration
+rate relative to the SOTA can reach up to 1.48.
+2
+Problem Definition
+The definition of the online multi-agent path finding prob-
+lem is that given a directed graph G(V, E), and a set of k
+agents a1, a2, a3 ... ak, find a collision-free path for each
+agent. The agent ai is described by the triplet (ts
+i, vs
+i , vg
+i ),
+meaning agent ai appears in the starting vertex vs
+i ∈ V in
+time point ts
+i and its goal is the vertex vg
+i ∈ V . In this paper,
+we call agent i starts at ts
+i. Without loss of generality, we
+assume 0 ≤ ts
+1 ≤ ts
+2 ≤ ... ≤ ts
+k. Specially, agents whose
+start time point is 0 can be seen as agents already in the
+scene before the environment starts to run, and we refer to
+the planning for these agents as the offline part of the on-
+line MAPF problem. In contrast, we refer to the planning
+after the system starts as the online part. In the beginning,
+all agents plan their path from their own start vertex to the
+goal vertex, while they do not know any information about
+the agents that will start in the future. After that, agents fol-
+low their own plan at each time. When it comes to the time
+point when new agents start, all agents need to replan their
+paths considering the new input of the online MAPF prob-
+lem. Let m be the number of time points when new agents
+start, and tnew
+1
+, tnew
+2
+... tnew
+m
+be the corresponding time point
+sequence. m might be smaller than k because there may be
+more than one agent starting at the same time point. The so-
+lution to an online MAPF problem is defined as a sequence
+of valid plans Π =
+�
+π0, π1, π2...πm�
+, where πj is a col-
+lection of all path plans at tnew
+j
+. Let pj
+i be the path plan of
+agent i in πj, and pj
+i[t] be the vertex of agent i in time point
+t in πj. We define pj
+i[tl : tr] as the concatenation of the
+path plan of agent i from time point tl to time point tr, i.e.
+pj
+i[u : v] = pj
+i[u]◦pj
+i[u+1]◦...◦pj
+i[v−1], where ◦ is the con-
+catenation operator. The execute plan of agent i is defined as
+Exi[Π] = p1
+i [tnew
+1
+: tnew
+2
+]◦p2
+i [tnew
+2
+: tnew
+3
+]◦...◦pm−1
+j
+[tnew
+n−1 :
+tnew
+n
+] ◦ pn
+j [tnew
+n
+: ∞], showing the actual path of agent i.
+In this paper, we focus on the variant:
+• We assume that the agent starts in the garage, which
+means that the new agent can choose to enter the start ver-
+tex at the start time or later. Before they enter, they wait
+in the garage and do not conflict with other agents. In ad-
+dition, we use the setting of disappearing at the goal ver-
+tex. Under these two assumptions, the problem is always
+solvable if the offline part is solvable and each agent has a
+path from its initial location to its goal location, as proved
+in Proposition 2 in (ˇSvancara et al. 2019). Although we
+use these two assumptions, our proposed method can be
+easily extended to other assumptions at the start and goal.
+• We only consider vertex conflict and edge conflict. Two
+agents collide iff they occupy the same vertex or cross
+the same edge in opposite directions at the same time.
+Two objectives are commonly used for offline MAPF prob-
+lems, minimizing makespan and minimizing sum-of-cost
+(SOC). Makespan is the maximum complete time above all
+agents. However, minimizing makespan is improper for the
+online MAPF problem because new agents will continu-
+ously be added to the environment, and the later added agent
+will more likely affect the objective. SOC is the summation
+of the cost of all agents’ path plans. However, two online
+MAPF solvers are not comparable in SOC directly because
+SOC cannot measure the exact quality of the two solvers.
+For example, two solvers s1 and s2 are used to solve the
+instances in Figure 1. At time point 0, a1 starts in A4. It
+has two paths with the same cost to its goal D1. Assume
+s1 choose P1 and s2 choose P2. Now considering for s1, a1
+goes to B4 at time point 1. In the first instance, a2 appears,
+the path of a1 will not be affected, and it will continuously
+follow the path [B4, C4, D4, D3, D2, D1] with length 6.
+However, in another instance, a′
+2 appears, the path of a1 will
+make a detour [B4, A4, A3, A2, A1, B1, C1, D1] with
+length 8. The symmetrical situation will appear on s2. We
+cannot say s1 is better than s2 or not because the actual cost
+depends on the future agents, which is unpredictable at early
+time points. Using SOC directly can not judge the quality of
+the solver. We define a solver as a snapshot optimal solver if
+the solver can get optimal paths in terms of SOC, assuming
+no new agent will appear in the future. A snapshot optimal
+solver is better than a non-optimal solver in solution quality.
+3
+Methodology
+Our approach is a three-level method. Figure 2 shows the
+architecture of the method. The high-level solver is the Sus-
+tainable Replan algorithm (SR), which simulates the envi-
+ronment and maintains the planning context of all agents.
+
+Figure 2: The architecture of the three-level approach. The SR algorithm is the high-level solver, simulating the environment
+and managing the planning context. The SCBS algorithm is the middle-level solver, which builds a conflict tree and extracts the
+individual planning context. The low-level solver, the SRSIPP algorithm, uses backward search on the TIS state for single-agent
+path planning.
+The Sustainable Conflict-Based Search algorithm (SCBS),
+the middle-level solver, plans the optimal path for multi-
+agents and manages the planning context. The low-level
+solver, Sustainable Reverse Safe Interval Path Planning (SR-
+SIPP), solves a single-agent problem under a set of con-
+straints.
+3.1
+Sustainable Replan Algorithm
+SR algorithm is the highest solver. It can simulate the scene
+and maintain the planning context sustainably. When one or
+more agents appear, the algorithm will do replanning for all
+agents. Figure 2 shows an example for the SR algorithm. The
+’W’ in the figure means the action is waiting in the garage.
+We define pc as the planning context, a two-level hash
+table, to save all the planning context. Its keys are the agent’s
+id and all constraints on this agent, while its values can be
+determined by its lower-level solvers. We will describe the
+specific planning context in the later subsections.
+The pseudo-code is shown in Algorithm 1. Let tc be the
+current time point, vc be the current vertex of the agent lo-
+cated, A be the agent set that has started, A+ be the new
+agent set appearing in time point tc, and Ex be the execu-
+tion plan. In lines 1-8, the environment is simulated to time
+point tc. If an agent a reaches its goal before time point tc,
+all related elements in A and pc will be removed. Otherwise,
+the current vertex vc of the agent a will be obtained from the
+previous execute plan Ex. In line 10, the SCBS algorithm
+calculates the optimal path plan p. In line 11, the execution
+plan is updated by the p, deleting the path from time point tc
+and concatenating the new path plan to the execution plan.
+Algorithm 1: Sustainable Replanning
+Input: original agent set A, new agent set A+, execute plan
+Ex, current time point tc, planning context pc
+1: for agent a in A do
+2:
+if a reach goal before time tc then
+3:
+A ← A \ {a}
+4:
+Remove all planning context of a in pc.
+5:
+else
+6:
+Update a.vc by Ex.
+7:
+end if
+8: end for
+9: A ← A ∪ A+.
+10: p, pc ← SCBS(A, tc, pc) // Algorithm 2
+11: Update Ex by p.
+12: return A, Ex, pc
+3.2
+Sustainable Conflict-Based Search Algorithm
+The Sustainable Conflict-Based Search algorithm (SCBS)
+calculates the multi-agent path plan and maintains the plan-
+ning context sustainably. It is extended from the Conflict-
+Based Search algorithm (CBS) (Sharon et al. 2015). The
+main difference between SCBS and CBS is the processing
+of the planning context.
+An example of using the SCBS algorithm is shown in Fig-
+ure 2. Before each low-level search, the planning context
+directly related to the low-level search will be extracted ac-
+cording to the agent and its related constraints. We name
+this part of the planning context as individual planning con-
+text and use ipc to represent it. During the low-level search,
+
+SR
+Planning Context
+ai
+con1
+con2
+a2
+a2
+CLOSED, OPEN
+CLOSED, OPEN
+a3
+a2
+......
+a2
+...
+con2
+con1
+Time Point 1
+Time Point 3
+CLOSED, OPEN
+CLOSED, OPEN
+SCBS
+Paths: .....
+Cons: @
+a3
+Icon1
+i con2
+ Individual Planning Context
+Paths: ..
+Paths: ....
+i CLOSED, OPEN
+CLOSED, OPEN
+Cost:
+Cost: ..
+CLOSED, OPEN
+Cons: ((t4, a1, V4))
+Cons: [(t4, a4, V4))
+··
+a4
+Icon1
+con2
+SRSIPP
+CLOSED, OPEN
+CLOSED, OPEN
+.....
+Path Building
+Backward Search on TIS State(a) Forward search on TS states.
+(b) Backward search on TS states.
+(c) Backward search on TIS states. The number
+in the block is the cost to vg.
+(d) Path building on TIS states.
+Figure 3: (a)-(c) are three different search methods on the same graph and constraints. (d) is based on (c). The number near the
+block shows the time point or the time interval.
+ipc is modified to fit the new instance. After the low-level
+search, the new ipc will be put back into pc for usage in
+later iterations.
+Algorithm 2 shows the pseudo-code. In lines 5-7 and 25-
+27, ipc is filtered from pc by the function GetIPC. After
+using the low-level solver, the new ipc is placed back to pc.
+3.3
+Sustainable Reverse Safe Interval Path
+Planning Algorithm
+We now introduce the Sustainable Reverse Safe Interval
+Path Planning algorithm (SRSIPP). The SRSIPP is a single-
+agent solver based on A* (Hart, Nilsson, and Raphael
+1968) and SIPP (Phillips and Likhachev 2011), designed for
+reusing the previous individual planning context to minimize
+the complexity of searching. We omit the agent index i and
+the current number of the planning iteration j in all sym-
+bols when discussing the SRSIPP algorithm, e.g. ts
+i,j, tg
+i,j,
+vs
+i , vg
+i to ts, tg. Let vc be the agent’s current vertex, and
+sc = (tc, vc) be the agent’s current state.
+In the online MAPF, agents may replan while executing
+their plan. Although the starting vertex of each planning is
+different, the ending vertex is invariant. SRSIPP uses this
+property to achieve the target of reusing the previous plan-
+ning context. For some single-agent solvers, the agent is
+planned from its current state to its goal through the edges.
+These search methods are called forward search. The plan-
+ning can also search from the goal to its current state through
+the reverse edges. These search methods are called backward
+search. The SRSIPP is a backward search algorithm.
+In the MAPF problem, most single-agent search methods
+are forward search on the time-space (TS) state. An example
+is shown in Figure 3(a). However, since the entire search tree
+is rooted at the start vertex, which changes with each search,
+the forward search cannot reuse previous planning informa-
+tion. Observing that the goal vertex is invariant for the same
+agent, we can set the goal vertex as the root of the search
+tree to reuse this tree in the following search. However, we
+cannot predict the arrival time before the search starts. For
+the optimality of the algorithm, all states that reach the goal
+earlier must be fully searched before states that arrive later,
+resulting in a large amount of additional computation. Fig-
+ure 3(b) shows an example.
+To speed up the calculation, we propose to search on the
+time-interval-space (TIS) state. Figure 3(c) shows an exam-
+ple. Let ([tl, tr], v) be the TIS state where [tl, tr] is a time
+interval and v is the vertex, and (t, v) be a TS state where t
+is a time point. The TIS state ([tl, tr], v) contains a collection
+of TS states {(t, v)|t ∈ [tl, tr]}. Let gT S(s) and gT IS(s) be
+the cost from a TS and TIS state to vg. All TS states in the
+same TIS state can use the same vertices sequence as the
+shortest path to the goal. Formally, we have
+∀t ∈ [tl, tr], gT IS(([tl, tr], v)) = gT S((t, v)).
+(1)
+We refer to the function value of gT S(s) and gT IS(s) as the
+g value of the TS state and the TIS state, respectively. A TIS
+state is valid if and only if it does not cover any constrained
+
+22
+V1
+2522
+21
+V51
+2
+0
+V2
+3
+V5
+2
+1
+V3
+V4Algorithm 2: SCBS
+Input: agents A, current time point tc, planning context pc
+1: OPEN ← ∅
+2: R ← new node
+3: R.cons ← ∅
+4: for each agent ai do
+5:
+ipc ← GetIPC(pc,ai,R.cons[ai])
+6:
+R.path[ai], ipc ←
+SRSIPP(ai, NULL, tc, ipc) // Algorithm 3
+7:
+Update pc by ipc.
+8: end for
+9: R.cost ← calculate the SOC of P.paths
+10: OPEN ← OPEN ∪ {R}
+11: while OPEN ̸= ∅ do
+12:
+N ← minimum cost node from OPEN.
+13:
+OPEN ← OPEN\{N}
+14:
+L ← the earliest collision in N
+15:
+if L is None then
+16:
+return N.paths, pc
+17:
+end if
+18:
+C ← Get constraints from L
+19:
+for constraint c in C do
+20:
+P ← new node
+21:
+P.cons ← N.cons
+22:
+P.paths ← N.paths
+23:
+a ← c.agent
+24:
+Insert c in P.cons[a].
+25:
+ipc ← GetIPC(pc, a, P.cons[a])
+26:
+P.paths[a], ipc ←
+SRSIPP(a, P.cons[a], tc, ipc) // Algorithm 3
+27:
+Update pc by ipc.
+28:
+if P.path[a] is not NULL then
+29:
+P.cost ← calculate the SOC of P.paths
+30:
+OPEN ← OPEN ∪ {P}
+31:
+end if
+32:
+end for
+33: end while
+TS states or cover TS states with a time point less than ts. A
+maximum TIS state is a valid TIS state whose time interval
+is not a subset of other valid TIS states on the same vertex.
+Before searching a vertex, all the maximum TIS states in
+the vertex will be created. Their g values are set to infinity,
+except that the g values of TIS states on vg are set to 0.
+The procedure of expanding a state for backward search
+is described as follows. The actions of the search include
+moving to a neighbor vertex through reverse edges and stay-
+ing in the same vertex. We use ([tl, tr], v) to represent the
+TIS state that needs to expand. We define a TIS state s′
+as a dummy son of another TIS s iff all TS states in s′
+can take one action to one of TS states in s in the for-
+ward direction. The cost of the dummy son will be one
+more than the original state, i.e., gT IS(s′) = gT IS(s) + 1.
+Let N(v) = {v′|((v′, v) ∈ E) ∨ (v′ = v)} be the neighbor-
+hood of v, and ds(([tl, tr], v)) = {([t′
+l, t′
+r], v′)|v′ ∈ N(v)}
+be the dummy son set of ([tl, tr], v). For the dummy son
+state ([t′
+l, t′
+r], v′) ∈ ds(([tl, tr], v)). We set
+t′
+l = max(ts, tl − 1)
+t′
+r = tr − 1
+(2)
+The dummy son is used to update all current TIS states
+on the same vertex. If the entire TIS state can be improved,
+the cost of the TIS state can be modified directly. Suppose
+only part of the TIS state can be improved due to the time
+interval coverage. In that case, the TIS state will be split into
+several TIS states according to the time interval coverage,
+and only the state completely covered by the dummy son’s
+time interval will be updated. Figure 4 shows an example.
+We use A* for the backward search. Let hT IS(s) be the
+heuristic function of the cost estimation from the TIS state s
+to sc, and hv(v) be the heuristic function of the path length
+estimation from vertex v and vc. We define hT IS(s) as
+hT IS(([tl, tr], v)) = max(max(tl − tc, 0), hv(v))
+(3)
+where tl ≥ ts. The states, where tr < ts, will not be
+searched, and the heuristic function for these states is un-
+defined. In the 4-neighbor grid, hv(v) is usually defined by
+the Manhattan distance to the goal point, i.e.,
+hv(v) = |vx − vg
+x| + |vy − vg
+y|
+(4)
+where (vx, vy) is the coordination of v and (vg
+x, vg
+y) is the
+coordination of vg. The evaluation function of a TIS state is
+defined as follows.
+fT IS(s) = gT IS(s) + hT IS(s)
+(5)
+Let the function value of hT IS(s) and fT IS(s) be the h
+value and the f value of a TIS state s, respectively.
+In the SRSIPP, the individual planning context includes
+the open list and the closed list. We use OPEN and
+CLOSED to represent them. At the beginning of the new
+search, we adjust the individual planning context to fit the
+new planning. Specifically, we recalculate the h value and
+the f value of all states in the OPEN, according to the new
+current state and Equations (3, 5). The CLOSED can be
+used directly without modification. After the adjustment, the
+new search can reuse the OPEN and the CLOSED of the
+previous search.
+The pseudo-code is shown in Algorithm 3. In the code,
+a.vc and a.vg are the current vertex and the goal vertex of
+the agent a. In addition, s.tl and s.tr are the endpoints of the
+time interval in s. The g value, h value and f value of state
+s are saved in s.g, s.h and s.f, respectively. A state is termi-
+nal state if the state is the optimal final state for the search.
+We use ts to save the terminal state and cts to save all can-
+didate terminal states. More specifically, cts saves all closed
+states in the vertex a.vc, which is reachable for the agent,
+i.e., tc ≤ s.tr. In line 1, the individual planning context is
+extracted. If the current state is invalid, return directly (lines
+2-4). In line 5, we update all states’ h value and f value in
+OPEN. In line 6, if the TIS states on a.vg have not been
+created, create all maximum TIS states and put them into
+the OPEN. In lines 7-12, the function StopCheck is used
+to check whether the search can stop. If yes, build the path
+
+Figure 4: An example to show the process of updating the cost of TIS states. The blocks indicate the time interval of the state,
+and the number in the block shows the cost to vg. The first row and the second row show the TIS state ([t0, t1], v) and its dummy
+son state ([t′
+0, t′
+1], v). The third row indicates all valid TIS states in v before being updated. The fourth line shows the updated
+TIS states. The first state cannot be improved, while for the second state, the whole state can be improved. For the third state,
+only part of the time interval is covered by [t′
+0, t′
+1]. The state is split into two states, and only the cost of the covered state is
+updated. The time interval of the fourth state is not covered, so it is not affected. The grey block shows the improved TIS states.
+by the function BuildPath and return directly (We will dis-
+cuss the detail of StopCheck and BuildPath later). Oth-
+erwise, the search starts. In each iteration, get the state with
+minimum f value in the OPEN (line 14). If the time inter-
+val cannot cover any time point after tc, the state is useless
+for the current and later searches. We ignore it and go to the
+next iteration of the while loop (lines 15-17). In lines 18-27,
+dummy sons are generated to update the states. In line 29,
+we update the OPEN, the CLOSED, and the cts. Finally,
+we check whether the search can stop (lines 30-32). If no,
+go to the next iteration.
+The StopCheck algorithm checks whether the search can
+stop and finds the best terminal state. When finding a better
+goal state out of cps is impossible, we stop searching. There
+are two different scenarios for the stop. If the agent is in
+the scene, the search stops when a state in cps covers tc.
+Otherwise, the agent can choose a time point to enter the
+scene. Supposed a state ([tl, tr], v) is selected as the terminal
+state, the best enter time point is max(tl, tc), and the total
+cost from agents’ current TS state (tc, vc) to vertex vg is
+max(tl − tc, 0) + gT IS(([tl, tr], v)). If the minimum total
+cost of choosing a state in cps is less than or equal to the f
+value of the current expanded state, no better solution can be
+found, and the search can stop.
+The pseudo-code of the StopCheck algorithm is shown
+in Algorithm 4. In lines 1-3, if there is no element in cts,
+the search can not stop. In lines 4-10, if the agent is in the
+scene, the search can stop only when a state in cts covers tc.
+In lines 12-18, if the agent is not in the scene, find the state
+with minimum total cost. If the cost is not higher than the
+minimum f value of all nodes in the OPEN, the search can
+stop and return the best terminal state.
+The BuildPath function in Algorithm 3 builds the final
+TS state path. After getting to the terminal state, we back-
+track to get a TIS path. Based on it, we build the TS path as
+the solution. Specially, if the agent is not in the scene and the
+current time point is earlier than any time point in the termi-
+nal state’s time interval, the agent will wait until it reaches
+the earliest time point of the target TIS state and then enter
+the scene. Figure 3(d) shows an example of the path build-
+ing, selecting ([3, ∞], v1) as the terminal state.
+4
+Theoretical Analysis
+Theorem 1. If hv(v) is admissible and satisfies the con-
+sistency assumption, when the first return value of the
+StopCheck function is true, it is impossible to have a better
+terminal state out of cts.
+Proof. The proof is given in the appendix.
+Theorem 2. If hv(v) is admissible and satisfies the con-
+sistency assumption, the SRISPP algorithm is complete and
+optimal.
+Proof. If hv(v) is admissible and satisfies the consistency
+assumption, then hT IS(s) is also admissible and satisfies the
+consistency assumption. It is proved in the appendix.
+If it is the first planning for the configuration of a and
+cons, the OPEN and CLOSED are empty initially. It is a
+standard A*, and the search’s completeness and optimality
+are satisfied.
+If the OPEN and CLOSED are not empty at the be-
+ginning of the search, the state in the CLOSED will not be
+reopened, and the g value of the state is already the smallest
+cost to the goal vertex. For the state in the OPEN, we up-
+date their h value and f value to fit the new situation. The
+scenario can be seen starting from a snapshot in the standard
+A*, except that some states are closed in advance. However,
+the early closed nodes will not affect the completeness and
+optimality of the algorithm because all their unclosed neigh-
+bors are in the OPEN.
+Combining theorem 1 and the above discussions, the the-
+orem is proved.
+Corollary 1. If hv(v) is admissible and satisfies the consis-
+tency assumption, SCBS is complete and optimal.
+Corollary 2. If hv(v) is admissible and satisfies the consis-
+tency assumption, SR is complete and snapshot optimal.
+These two corollaries can be proved according to the
+property of CBS, and RA algorithm (Sharon et al. 2015;
+ˇSvancara et al. 2019). Because Theorem 2 is proved and the
+operations on planning context in SCBS and SR will not af-
+fect completeness and optimality, the corollaries are proved.
+
+3
+4
+4-1
+5
+61
+5
+:6
+4
+4
+5Algorithm 3: SRSIPP
+Input:agent a, constraints cons, current time point tc, indi-
+vidual planning context ipc
+1: OPEN, CLOSED ← ipc
+2: if a is in the scene and (tc, a.vc) ∈ cons then
+3:
+return false, ipc
+4: end if
+5: Update h value and f value of states in OPEN.
+6: Create maximum TIS states in v′ by cons if the states
+are uncreated, and put them into OPEN.
+7: fmin ← the smallest f value in OPEN
+8: cps ← {([tl, tr], v) ∈ CLOSED|a.vc = v∧
+a.ts ≤ tr)}
+9: stop, ts ← StopCheck(cps, fmin, a) // Algorithm 4
+10: if stop then
+11:
+return BuildPath(ts, a), {OPEN, CLOSED}
+12: end if
+13: while OPEN is not empty do
+14:
+s ← the TIS state with minimum f value in OPEN
+15:
+if s.tr < tc then
+16:
+continue
+17:
+end if
+18:
+for each vertex v′ in N(s.v) do
+19:
+ds ← the dummy son of s in v′
+20:
+Create maximum TIS states in v′ by cons if the
+states are uncreated, and put them into OPEN.
+21:
+for each TIS state s′ in v′ do
+22:
+if s′ can be improved by ds then
+23:
+S′
+new ← New states after improving s′
+24:
+OPEN ← OPEN\{s′} ∪ S′
+new
+25:
+end if
+26:
+end for
+27:
+end for
+28:
+stop, ts ← StopCheck(cps, s.f, a) // Algorithm 4
+29:
+Update OPEN, CLOSED and cps by s.
+30:
+if stop then
+31:
+return BuildPath(ts, a), {OPEN, CLOSED}
+32:
+end if
+33: end while
+5
+Experiment
+The purpose of our experiments is to evaluate the computa-
+tional efficiency of the proposed approach. Two 4-neighbor
+grid map datasets are used with settings similar to (ˇSvancara
+et al. 2019), which is a small grid map dataset and a large
+grid map dataset, respectively. We perform online MAPF in
+these grid maps. Specifically, we move each of the agents
+from one cell to another. During this period, there will be
+new agents starting at any time.
+We use success rate and average running time as the met-
+rics. The running time limit is 30 seconds. If the algorithm
+run exceeds the time limit, the experimental instance is un-
+successful and uses the time limit as the running time. We
+make statistics based on the number of agents. For each
+number of agents, it has 100 instances in both datasets.
+The experiments assume no agents are in the scene at the
+beginning. On the one hand, the offline parts of algorithms
+Algorithm 4: StopCheck
+Input: candidate terminal state set cts, the minimum esti-
+mated function value in the open list fmin, the agent a
+1: if cts is empty then
+2:
+return false, NULL
+3: end if
+4: if a is in the scene then
+5:
+s ← the state which covers tc
+6:
+if s is NULL then
+7:
+return false, NULL
+8:
+else
+9:
+return true, s
+10:
+end if
+11: else
+12:
+smin ← argmins∈cts(max(s.tl − tc, 0) + s.g)
+13:
+cmin ← mins∈cts(max(s.tl − tc, 0) + s.g)
+14:
+if cmin ≤ fmin then
+15:
+return true, smin
+16:
+else
+17:
+return false, NULL
+18:
+end if
+19: end if
+(a) Small grid maps.
+(b) Large grid map.
+Figure 5: Grids for experiments from (ˇSvancara et al. 2019).
+are the same. If some instances fail in the offline part, the
+online algorithm is not executed. These test cases are use-
+less for comparison. All randomly generated instances are
+always solvable if there are no agents in the scene in the be-
+ginning. On the other hand, all compared methods use iden-
+tical offline MAPF solvers. Ignoring it does not affect the
+comparison.
+We run the algorithms on an AMD R7-5800X CPU with
+4.40 GHz and 16GB RAM. Four baselines are selected for
+comparison:
+• RA+CBS+A*(A1): This algorithm uses the Replan All
+algorithm to solve the online MAPF problem. When new
+agents start, it uses the CBS algorithm to calculate the
+multi-agent path plan, whose low-level solver is A*.
+• RA+CBS+RSIPP(A2): This algorithm removes all sus-
+tainable operations from our proposed approach, i.e., all
+solvers do not maintain or use the planning context.
+• SR+SCBS+RSIPP(A3): For this algorithm, the low-
+level solver can not reuse the planning context. In the
+middle-level solver, if the agent strictly follows the pre-
+vious path in the node of the conflict tree, the low-level
+
+k
+A1
+A2
+A3
+A4
+10
+96%
+96%
+96%
+96%
+12
+87%
+84%
+86%
+87%
+15
+78%
+74%
+79%
+80%
+17
+65%
+63%
+63%
+64%
+20
+49%
+47%
+47%
+49%
+22
+36%
+35%
+37%
+37%
+25
+27%
+26%
+28%
+29%
+Table 1: Table of the success rate in small grids. k is the
+agent number.
+k
+A1
+A2
+A3
+A4
+10
+1.68(-)
+2.2(0.77)
+1.72(0.98)
+1.58(1.06)
+12
+5.65(-)
+5.96(0.95)
+5.35(1.06)
+4.77(1.18)
+15
+8.05(-)
+8.67(0.93)
+7.96(1.01)
+7.27(1.11)
+17
+12.26(-)
+12.61(0.97)
+11.96(1.03)
+11.54(1.06)
+20
+17.01(-)
+17.18(0.99)
+16.6(1.02)
+16.23(1.05)
+22
+21.08(-)
+22.02(0.96)
+20.83(1.01)
+20.15(1.05)
+25
+22.53(-)
+22.39(1.01)
+22.15(1.02)
+21.9(1.03)
+Table 2: Table of the running time and the speedup ratio
+in small grids. The first number in the cell shows the run-
+ning time(sec), and the number in parentheses indicates the
+speedup relative to A1. k is the agent number.
+solver won’t be called, and a suffix from the results of the
+previous planning is used as the results of this planning.
+• SR+SCBS+SRSIPP(A4): The proposed method.
+5.1
+Small Grid Map
+In the first dataset, 4 small grid maps are used, as shown
+in Figure 5(a). The start and goal points are randomly
+sampled in two cells of the opposing sides of the grids,
+and the start time point is uniformly sampled from [1, 30].
+Let k be the number of agents, which is in the range
+{10, 12, 15, 17, 20, 22, 25}. In each grid map, we generate
+25 experimental instances for each setting of the agent num-
+ber. For each number of agents, it has 25∗4 = 100 instances.
+Table 1 shows the result of success rate. Except when the
+agent number is 17, the success rate of A4 is larger than or
+equal to A1. Table 2 shows the running time of all baselines
+and the speedup ratio relative to A1 of other baselines. In
+the result, A2 did not obtain significant improvement, while
+A3 can speed up in most cases. The best performance comes
+from A4. It shows an improvement in average runtime rela-
+tive to A1 under all agent number settings and achieves the
+maximum speedup ratio in all baselines.
+5.2
+Large Grid Map
+In the second dataset, we use the large grid map shown
+in Figure 5(b). We generate 100 experimental instances for
+each setting of the agent number k in the range of [90, 100].
+The start time points are randomly sampled from [1, 100].
+An agent’s start point and goal point are sampled from two
+different sides.
+Table 3 and Table 4 show the result of the success rate,
+the average running time, and the speedup ratio relative to
+A1 of different baselines. A2 and A3 perform better than A1
+k
+A1
+A2
+A3
+A4
+90
+84%
+85%
+88%
+91%
+92
+82%
+84%
+86%
+89%
+94
+90%
+89%
+91%
+92%
+96
+75%
+77%
+81%
+84%
+98
+72%
+76%
+82%
+83%
+100
+54%
+69%
+72%
+77%
+Table 3: Table of the success rate in large grids. k is the agent
+number.
+k
+A1
+A2
+A3
+A4
+90
+10.09(-)
+8.98(1.12)
+7.48(1.35)
+6.06(1.67)
+92
+9.69(-)
+9.61(1.01)
+8.13(1.19)
+6.8(1.43)
+94
+8.04(-)
+8.27(0.97)
+6.59(1.22)
+5.52(1.46)
+96
+13.05(-)
+13.35(0.98)
+11.25(1.16)
+9.84(1.33)
+98
+13.37(-)
+12.4(1.08)
+10.5(1.27)
+9.21(1.45)
+100
+18.06(-)
+14.78(1.22)
+13.02(1.39)
+11.58(1.56)
+Table 4: Table of the running time and the speedup ratio
+in large grids. The first number in the cell shows the run-
+ning time(sec), and the number in parentheses indicates the
+speedup relative to A1. k is the agent number.
+in most cases, while A4 runs the fastest among all methods.
+In all instances, the average speedup ratio of A4 relative to
+A1 reaches 1.48.
+The running time of 92 and 94 agents are shorter than
+90 agents. It is because when the number of agents is large,
+the running time is not significantly influenced by the small
+increment of the agent number but is dominated by some
+hard-to-solve cases.
+5.3
+Discussion
+The improvement in the large grids is more obvious than in
+the small grids. We believe it is because of the path length.
+In the small grid maps, the path of agents is short. Sustain-
+able information can only be used a few times. In the large
+map, the path is much longer. Sustainable information is
+used more frequently, making A4 get a higher speedup ratio.
+6
+Conclusion
+We proposed a three-level algorithm to solve the online
+MAPF problem. Three levels are responsible for simulating
+the multi-agent online environment, solving the multi-agent
+path planning, and using the historical planning informa-
+tion to assist in solving the single-agent path planning. We
+proved the completeness and the snapshot optimality of our
+approach. The experiment shows that our proposed method
+runs faster than the SOTA algorithm. During the experiment,
+we also found that the performance in large grids is much
+better than in small grids. This is because the agent has a
+longer path in a larger grid so that the planning context can
+be reused more times. It shows that the longer the path, the
+better the acceleration effect of our method.
+In the future, more aspects of using sustainable informa-
+tion, such as building the conflict tree, will be explored to
+improve the efficiency of the algorithm further.
+
+References
+Choudhury, S.; Solovey, K.; Kochenderfer, M.; and Pavone,
+M. 2022. Coordinated Multi-Agent Pathfinding for Drones
+and Trucks over Road Networks. In Proceedings of the 21st
+International Conference on Autonomous Agents and Multi-
+agent Systems, 272–280.
+Hart, P. E.; Nilsson, N. J.; and Raphael, B. 1968. A for-
+mal basis for the heuristic determination of minimum cost
+paths. IEEE transactions on Systems Science and Cybernet-
+ics, 4(2): 100–107.
+Ma, H.; Koenig, S.; Ayanian, N.; Cohen, L.; H¨onig, W.; Ku-
+mar, T.; Uras, T.; Xu, H.; Tovey, C.; and Sharon, G. 2017a.
+Overview: Generalizations of multi-agent path finding to
+real-world scenarios. arXiv preprint arXiv:1702.05515.
+Ma, H.; Tovey, C.; Sharon, G.; Kumar, T.; and Koenig, S.
+2016. Multi-agent path finding with payload transfers and
+the package-exchange robot-routing problem. In Proceed-
+ings of the AAAI Conference on Artificial Intelligence, vol-
+ume 30.
+Ma, H.; Yang, J.; Cohen, L.; Kumar, T. S.; and Koenig, S.
+2017b. Feasibility study: Moving non-homogeneous teams
+in congested video game environments. In Thirteenth Artifi-
+cial Intelligence and Interactive Digital Entertainment Con-
+ference.
+Morris, R.; Pasareanu, C. S.; Luckow, K.; Malik, W.; Ma, H.;
+Kumar, T. S.; and Koenig, S. 2016. Planning, scheduling and
+monitoring for airport surface operations. In Workshops at
+the Thirtieth AAAI Conference on Artificial Intelligence.
+Phillips, M.; and Likhachev, M. 2011. Sipp: Safe interval
+path planning for dynamic environments. In 2011 IEEE In-
+ternational Conference on Robotics and Automation, 5628–
+5635. IEEE.
+Salzman, O.; and Stern, R. 2020. Research challenges and
+opportunities in multi-agent path finding and multi-agent
+pickup and delivery problems. In Proceedings of the 19th
+International Conference on Autonomous Agents and Multi-
+Agent Systems, 1711–1715.
+Sharon, G.; Stern, R.; Felner, A.; and Sturtevant, N. R. 2015.
+Conflict-based search for optimal multi-agent pathfinding.
+Artificial Intelligence, 219: 40–66.
+Stern, R. 2019. Multi-agent path finding–an overview. Arti-
+ficial Intelligence, 96–115.
+ˇSvancara, J.; Vlk, M.; Stern, R.; Atzmon, D.; and Bart´ak,
+R. 2019. Online multi-agent pathfinding. In Proceedings
+of the AAAI conference on artificial intelligence, volume 33,
+7732–7739.
+Wurman, P. R.; D’Andrea, R.; and Mountz, M. 2008. Co-
+ordinating hundreds of cooperative, autonomous vehicles in
+warehouses. AI magazine, 29(1): 9–9.
+Yu, J.; and LaValle, S. M. 2013. Structure and intractability
+of optimal multi-robot path planning on graphs. In Twenty-
+Seventh AAAI Conference on Artificial Intelligence.
+
diff --git a/BdE3T4oBgHgl3EQfUAoU/content/tmp_files/load_file.txt b/BdE3T4oBgHgl3EQfUAoU/content/tmp_files/load_file.txt
new file mode 100644
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@@ -0,0 +1,689 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf,len=688
+page_content='An Efficient Approach to the Online Multi-Agent Path Finding Problem  by Using Sustainable Information  1, 3Mingkai TANG, 1, 6Boyi LIU, 1, 4Yuanhang LI, 1, 2, 5Hongji LIU, 1, 2, 7Ming LIU, 1, 8Lujia WANG  1The Hong Kong University of Science and Technology  2The Hong Kong University of Science and Technology (Guangzhou)  {3mtangag, 4yliog, 5hliucq}@connect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='ust.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='hk, 6by.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='liu@ieee.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='org, {7eelium, 8eewanglj}@ust.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='hk  Abstract  Multi-agent path finding (MAPF) is the problem of mov-  ing agents to the goal vertex without collision.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the on-  line MAPF problem, new agents may be added to the envi-  ronment at any time, and the current agents have no infor-  mation about future agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The inability of existing online  methods to reuse previous planning contexts results in redun-  dant computation and reduces algorithm efficiency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Hence,  we propose a three-level approach to solve online MAPF uti-  lizing sustainable information, which can decrease its redun-  dant calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The high-level solver, the Sustainable Re-  plan algorithm (SR), manages the planning context and sim-  ulates the environment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The middle-level solver, the Sustain-  able Conflict-Based Search algorithm (SCBS), builds a con-  flict tree and maintains the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The low-level  solver, the Sustainable Reverse Safe Interval Path Planning  algorithm (SRSIPP), is an efficient single-agent solver that  uses previous planning context to reduce duplicate calcula-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Experiments show that our proposed method has sig-  nificant improvement in terms of computational efficiency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In  one of the test scenarios, our algorithm can be 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='48 times  faster than SOTA on average under different agent number  settings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  1  Introduction  The multi-agent path finding problem (MAPF) is finding  paths for a set of agents to move from their starting ver-  tex to the goal vertex without collision.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' MAPF has a wide  practical application, such as aircraft towing vehicles (Mor-  ris et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2016), warehouse robots (Wurman, D’Andrea, and  Mountz 2008), video games (Ma et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2017b) and urban  road networks (Choudhury et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  For MAPF, most works assume that the environment can  be fully captured before the system runs (Salzman and Stern  2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Stern 2019;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Ma et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2017a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Under this assumption,  the solution can be calculated in advance, and the agent only  needs to take actions along the pre-calculated plan at run-  time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' These path finding problems are referred to as offline  MAPF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However, in practice, the assumption is not always  guaranteed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' During the running of a system, new agents  might appear in the system suddenly, and agents need to  do replanning to fit the new situation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Recently, the online  MAPF problem (ˇSvancara et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2019) was proposed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It is  assumed that new agents may be added to the environment  at any time, and the current agents have no information about  Figure 1: An example of two online MAPF instances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In  both instances, a1 appears A4 at time point 0 and needs to  travel to D1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' P1 and P2 are two paths with equal costs for  a1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the first instance, a2 appears in C1 at time point 1,  and its goal is A2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the second instance, a′  2 appears in D2  at time point 1, and its goal is C4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  future agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' All agents in the environment need to do re-  planning to fit the new situation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Online MAPF is a problem of great practical importance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  For example, in a real-world warehouse system, the robot  frequently enters and exits the work area due to factors  such as charging or malfunction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Moreover, the time point  at which the robot re-enters the work area is unpredictable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The agents in the warehouse need to adjust their path due to  the appearance of a new agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Optimally solving the offline MAPF problem is NP-hard  (Yu and LaValle 2013;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Ma et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Compared with the  offline MAPF, which can calculate the paths before the sys-  tem runs, the online MAPF further needs to calculate high-  quality paths for all agents in real-time when new agents  appear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' ˇSvancara et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' proposed several methods to solve  the online MAPF problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The Replan Single algorithm  searches an optimal path for each new agent when they  appear, while all paths of the old agents remain the same.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The Replan Single Group algorithm jointly plans for all new  agents appearing at the same time, and the new agents’ path  plan cannot affect the old agents’ path plan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' These two al-  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='04446v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='MA]  11 Jan 2023  P1  α1  α2  P2  α2  α2  α2  α1gorithms can execute fast, but the solutions are not optimal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The Replan All algorithm replan for all agents without con-  sidering existing path plans when new agents appear, and  it can get high-quality solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However, each iteration of  planning in the Replan All algorithm has a high computa-  tional complexity when the number of agents becomes large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Considering reusing the information in previous planning  iterations to reduce the running time, we propose an efficient  algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In this paper, we refer to this kind of information  as sustainable information or planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Our method  consists of three levels of algorithms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We name the high-  level algorithm as the Sustainable Replan algorithm(SR).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It  simulates the environment and maintains the whole plan-  ning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The middle-level algorithm, the Sustainable  Conflict-Based Search Algorithm (SCBS), is called by SR  for searching the multi-agent path planning solution based  on current information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' SCBS uses the Sustainable Reverse  Safe Interval Path Planning algorithm (SRSIPP), which is  the low-level solver, for single-agent planning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Given that  each planning iteration for a single agent has the same goal  point, but different starting points, SRSIPP searches the path  in the backward direction (from goal point to starting point)  to reuse the previous planning information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The main contributions of this paper are as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We propose a three-level approach for reusing previous  planning context to reduce the running time for the online  MAPF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We prove the completeness and the snapshot optimality  of our approaches.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We performed detailed algorithm performance compar-  ison experiments with SOTA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The average acceleration  rate relative to the SOTA can reach up to 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  2  Problem Definition  The definition of the online multi-agent path finding prob-  lem is that given a directed graph G(V, E), and a set of k  agents a1, a2, a3 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' ak, find a collision-free path for each  agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The agent ai is described by the triplet (ts  i, vs  i , vg  i ),  meaning agent ai appears in the starting vertex vs  i ∈ V in  time point ts  i and its goal is the vertex vg  i ∈ V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In this paper,  we call agent i starts at ts  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Without loss of generality, we  assume 0 ≤ ts  1 ≤ ts  2 ≤ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' ≤ ts  k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Specially, agents whose  start time point is 0 can be seen as agents already in the  scene before the environment starts to run, and we refer to  the planning for these agents as the offline part of the on-  line MAPF problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In contrast, we refer to the planning  after the system starts as the online part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the beginning,  all agents plan their path from their own start vertex to the  goal vertex, while they do not know any information about  the agents that will start in the future.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' After that, agents fol-  low their own plan at each time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' When it comes to the time  point when new agents start, all agents need to replan their  paths considering the new input of the online MAPF prob-  lem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let m be the number of time points when new agents  start, and tnew  1  , tnew  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' tnew  m  be the corresponding time point  sequence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' m might be smaller than k because there may be  more than one agent starting at the same time point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The so-  lution to an online MAPF problem is defined as a sequence  of valid plans Π =  �  π0, π1, π2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='πm�  , where πj is a col-  lection of all path plans at tnew  j  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let pj  i be the path plan of  agent i in πj, and pj  i[t] be the vertex of agent i in time point  t in πj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We define pj  i[tl : tr] as the concatenation of the  path plan of agent i from time point tl to time point tr, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  pj  i[u : v] = pj  i[u]◦pj  i[u+1]◦.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='◦pj  i[v−1], where ◦ is the con-  catenation operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The execute plan of agent i is defined as  Exi[Π] = p1  i [tnew  1  : tnew  2  ]◦p2  i [tnew  2  : tnew  3  ]◦.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='◦pm−1  j  [tnew  n−1 :  tnew  n  ] ◦ pn  j [tnew  n  : ∞], showing the actual path of agent i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In this paper, we focus on the variant:  We assume that the agent starts in the garage, which  means that the new agent can choose to enter the start ver-  tex at the start time or later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Before they enter, they wait  in the garage and do not conflict with other agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In ad-  dition, we use the setting of disappearing at the goal ver-  tex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Under these two assumptions, the problem is always  solvable if the offline part is solvable and each agent has a  path from its initial location to its goal location, as proved  in Proposition 2 in (ˇSvancara et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Although we  use these two assumptions, our proposed method can be  easily extended to other assumptions at the start and goal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  We only consider vertex conflict and edge conflict.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Two  agents collide iff they occupy the same vertex or cross  the same edge in opposite directions at the same time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Two objectives are commonly used for offline MAPF prob-  lems, minimizing makespan and minimizing sum-of-cost  (SOC).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Makespan is the maximum complete time above all  agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However, minimizing makespan is improper for the  online MAPF problem because new agents will continu-  ously be added to the environment, and the later added agent  will more likely affect the objective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' SOC is the summation  of the cost of all agents’ path plans.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However, two online  MAPF solvers are not comparable in SOC directly because  SOC cannot measure the exact quality of the two solvers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  For example, two solvers s1 and s2 are used to solve the  instances in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' At time point 0, a1 starts in A4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It  has two paths with the same cost to its goal D1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Assume  s1 choose P1 and s2 choose P2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Now considering for s1, a1  goes to B4 at time point 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the first instance, a2 appears,  the path of a1 will not be affected, and it will continuously  follow the path [B4, C4, D4, D3, D2, D1] with length 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  However, in another instance, a′  2 appears, the path of a1 will  make a detour [B4, A4, A3, A2, A1, B1, C1, D1] with  length 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The symmetrical situation will appear on s2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We  cannot say s1 is better than s2 or not because the actual cost  depends on the future agents, which is unpredictable at early  time points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Using SOC directly can not judge the quality of  the solver.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We define a solver as a snapshot optimal solver if  the solver can get optimal paths in terms of SOC, assuming  no new agent will appear in the future.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' A snapshot optimal  solver is better than a non-optimal solver in solution quality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  3  Methodology  Our approach is a three-level method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Figure 2 shows the  architecture of the method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The high-level solver is the Sus-  tainable Replan algorithm (SR), which simulates the envi-  ronment and maintains the planning context of all agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Figure 2: The architecture of the three-level approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The SR algorithm is the high-level solver, simulating the environment  and managing the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The SCBS algorithm is the middle-level solver, which builds a conflict tree and extracts the  individual planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The low-level solver, the SRSIPP algorithm, uses backward search on the TIS state for single-agent  path planning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The Sustainable Conflict-Based Search algorithm (SCBS),  the middle-level solver, plans the optimal path for multi-  agents and manages the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The low-level  solver, Sustainable Reverse Safe Interval Path Planning (SR-  SIPP), solves a single-agent problem under a set of con-  straints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='1  Sustainable Replan Algorithm  SR algorithm is the highest solver.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It can simulate the scene  and maintain the planning context sustainably.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' When one or  more agents appear, the algorithm will do replanning for all  agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Figure 2 shows an example for the SR algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The  ’W’ in the figure means the action is waiting in the garage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  We define pc as the planning context, a two-level hash  table, to save all the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Its keys are the agent’s  id and all constraints on this agent, while its values can be  determined by its lower-level solvers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We will describe the  specific planning context in the later subsections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The pseudo-code is shown in Algorithm 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let tc be the  current time point, vc be the current vertex of the agent lo-  cated, A be the agent set that has started, A+ be the new  agent set appearing in time point tc, and Ex be the execu-  tion plan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In lines 1-8, the environment is simulated to time  point tc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If an agent a reaches its goal before time point tc,  all related elements in A and pc will be removed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Otherwise,  the current vertex vc of the agent a will be obtained from the  previous execute plan Ex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In line 10, the SCBS algorithm  calculates the optimal path plan p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In line 11, the execution  plan is updated by the p, deleting the path from time point tc  and concatenating the new path plan to the execution plan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Algorithm 1: Sustainable Replanning  Input: original agent set A, new agent set A+, execute plan  Ex, current time point tc, planning context pc  1: for agent a in A do  2:  if a reach goal before time tc then  3:  A ← A \\ {a}  4:  Remove all planning context of a in pc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  5:  else  6:  Update a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vc by Ex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  7:  end if  8: end for  9: A ← A ∪ A+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  10: p, pc ← SCBS(A, tc, pc) // Algorithm 2  11: Update Ex by p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  12: return A, Ex, pc  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='2  Sustainable Conflict-Based Search Algorithm  The Sustainable Conflict-Based Search algorithm (SCBS)  calculates the multi-agent path plan and maintains the plan-  ning context sustainably.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It is extended from the Conflict-  Based Search algorithm (CBS) (Sharon et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The  main difference between SCBS and CBS is the processing  of the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  An example of using the SCBS algorithm is shown in Fig-  ure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Before each low-level search, the planning context  directly related to the low-level search will be extracted ac-  cording to the agent and its related constraints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We name  this part of the planning context as individual planning con-  text and use ipc to represent it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' During the low-level search,  SR  Planning Context  ai  con1  con2  a2  a2  CLOSED, OPEN  CLOSED, OPEN  a3  a2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='.  a2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  con2  con1  Time Point 1  Time Point 3  CLOSED, OPEN  CLOSED, OPEN  SCBS  Paths: .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Cons: @  a3  Icon1  i con2  Individual Planning Context  Paths: .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='.  Paths: .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='.  i CLOSED, OPEN  CLOSED, OPEN  Cost:  Cost: .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='.  CLOSED, OPEN  Cons: ((t4, a1, V4))  Cons: [(t4, a4, V4))  ··  a4  Icon1  con2  SRSIPP  CLOSED, OPEN  CLOSED, OPEN  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Path Building  Backward Search on TIS State(a) Forward search on TS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  (b) Backward search on TS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  (c) Backward search on TIS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The number  in the block is the cost to vg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  (d) Path building on TIS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Figure 3: (a)-(c) are three different search methods on the same graph and constraints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' (d) is based on (c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The number near the  block shows the time point or the time interval.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  ipc is modified to fit the new instance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' After the low-level  search, the new ipc will be put back into pc for usage in  later iterations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Algorithm 2 shows the pseudo-code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In lines 5-7 and 25-  27, ipc is filtered from pc by the function GetIPC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' After  using the low-level solver, the new ipc is placed back to pc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='3  Sustainable Reverse Safe Interval Path  Planning Algorithm  We now introduce the Sustainable Reverse Safe Interval  Path Planning algorithm (SRSIPP).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The SRSIPP is a single-  agent solver based on A* (Hart, Nilsson, and Raphael  1968) and SIPP (Phillips and Likhachev 2011), designed for  reusing the previous individual planning context to minimize  the complexity of searching.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We omit the agent index i and  the current number of the planning iteration j in all sym-  bols when discussing the SRSIPP algorithm, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' ts  i,j, tg  i,j,  vs  i , vg  i to ts, tg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let vc be the agent’s current vertex, and  sc = (tc, vc) be the agent’s current state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In the online MAPF, agents may replan while executing  their plan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Although the starting vertex of each planning is  different, the ending vertex is invariant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' SRSIPP uses this  property to achieve the target of reusing the previous plan-  ning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For some single-agent solvers, the agent is  planned from its current state to its goal through the edges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  These search methods are called forward search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The plan-  ning can also search from the goal to its current state through  the reverse edges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' These search methods are called backward  search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The SRSIPP is a backward search algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In the MAPF problem, most single-agent search methods  are forward search on the time-space (TS) state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' An example  is shown in Figure 3(a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However, since the entire search tree  is rooted at the start vertex, which changes with each search,  the forward search cannot reuse previous planning informa-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Observing that the goal vertex is invariant for the same  agent, we can set the goal vertex as the root of the search  tree to reuse this tree in the following search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However, we  cannot predict the arrival time before the search starts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For  the optimality of the algorithm, all states that reach the goal  earlier must be fully searched before states that arrive later,  resulting in a large amount of additional computation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Fig-  ure 3(b) shows an example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  To speed up the calculation, we propose to search on the  time-interval-space (TIS) state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Figure 3(c) shows an exam-  ple.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let ([tl, tr], v) be the TIS state where [tl, tr] is a time  interval and v is the vertex, and (t, v) be a TS state where t  is a time point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The TIS state ([tl, tr], v) contains a collection  of TS states {(t, v)|t ∈ [tl, tr]}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let gT S(s) and gT IS(s) be  the cost from a TS and TIS state to vg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' All TS states in the  same TIS state can use the same vertices sequence as the  shortest path to the goal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Formally, we have  ∀t ∈ [tl, tr], gT IS(([tl, tr], v)) = gT S((t, v)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  (1)  We refer to the function value of gT S(s) and gT IS(s) as the  g value of the TS state and the TIS state, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' A TIS  state is valid if and only if it does not cover any constrained  22  V1  2522  21  V51  2  0  V2  3  V5  2  1  V3  V4Algorithm 2: SCBS  Input: agents A, current time point tc, planning context pc  1: OPEN ← ∅  2: R ← new node  3: R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons ← ∅  4: for each agent ai do  5:  ipc ← GetIPC(pc,ai,R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons[ai])  6:  R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='path[ai], ipc ←  SRSIPP(ai, NULL, tc, ipc) // Algorithm 3  7:  Update pc by ipc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  8: end for  9: R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cost ← calculate the SOC of P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='paths  10: OPEN ← OPEN ∪ {R}  11: while OPEN ̸= ∅ do  12:  N ← minimum cost node from OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  13:  OPEN ← OPEN\\{N}  14:  L ← the earliest collision in N  15:  if L is None then  16:  return N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='paths, pc  17:  end if  18:  C ← Get constraints from L  19:  for constraint c in C do  20:  P ← new node  21:  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons ← N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons  22:  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='paths ← N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='paths  23:  a ← c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='agent  24:  Insert c in P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons[a].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  25:  ipc ← GetIPC(pc, a, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons[a])  26:  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='paths[a], ipc ←  SRSIPP(a, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cons[a], tc, ipc) // Algorithm 3  27:  Update pc by ipc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  28:  if P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='path[a] is not NULL then  29:  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='cost ← calculate the SOC of P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='paths  30:  OPEN ← OPEN ∪ {P}  31:  end if  32:  end for  33: end while  TS states or cover TS states with a time point less than ts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' A  maximum TIS state is a valid TIS state whose time interval  is not a subset of other valid TIS states on the same vertex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Before searching a vertex, all the maximum TIS states in  the vertex will be created.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Their g values are set to infinity,  except that the g values of TIS states on vg are set to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The procedure of expanding a state for backward search  is described as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The actions of the search include  moving to a neighbor vertex through reverse edges and stay-  ing in the same vertex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We use ([tl, tr], v) to represent the  TIS state that needs to expand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We define a TIS state s′  as a dummy son of another TIS s iff all TS states in s′  can take one action to one of TS states in s in the for-  ward direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The cost of the dummy son will be one  more than the original state, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=', gT IS(s′) = gT IS(s) + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Let N(v) = {v′|((v′, v) ∈ E) ∨ (v′ = v)} be the neighbor-  hood of v, and ds(([tl, tr], v)) = {([t′  l, t′  r], v′)|v′ ∈ N(v)}  be the dummy son set of ([tl, tr], v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For the dummy son  state ([t′  l, t′  r], v′) ∈ ds(([tl, tr], v)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We set  t′  l = max(ts, tl − 1)  t′  r = tr − 1  (2)  The dummy son is used to update all current TIS states  on the same vertex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the entire TIS state can be improved,  the cost of the TIS state can be modified directly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Suppose  only part of the TIS state can be improved due to the time  interval coverage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In that case, the TIS state will be split into  several TIS states according to the time interval coverage,  and only the state completely covered by the dummy son’s  time interval will be updated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Figure 4 shows an example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  We use A* for the backward search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Let hT IS(s) be the  heuristic function of the cost estimation from the TIS state s  to sc, and hv(v) be the heuristic function of the path length  estimation from vertex v and vc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We define hT IS(s) as  hT IS(([tl, tr], v)) = max(max(tl − tc, 0), hv(v))  (3)  where tl ≥ ts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The states, where tr < ts, will not be  searched, and the heuristic function for these states is un-  defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the 4-neighbor grid, hv(v) is usually defined by  the Manhattan distance to the goal point, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=',  hv(v) = |vx − vg  x| + |vy − vg  y|  (4)  where (vx, vy) is the coordination of v and (vg  x, vg  y) is the  coordination of vg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The evaluation function of a TIS state is  defined as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  fT IS(s) = gT IS(s) + hT IS(s)  (5)  Let the function value of hT IS(s) and fT IS(s) be the h  value and the f value of a TIS state s, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In the SRSIPP, the individual planning context includes  the open list and the closed list.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We use OPEN and  CLOSED to represent them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' At the beginning of the new  search, we adjust the individual planning context to fit the  new planning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Specifically, we recalculate the h value and  the f value of all states in the OPEN, according to the new  current state and Equations (3, 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The CLOSED can be  used directly without modification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' After the adjustment, the  new search can reuse the OPEN and the CLOSED of the  previous search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The pseudo-code is shown in Algorithm 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the code,  a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vc and a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vg are the current vertex and the goal vertex of  the agent a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In addition, s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='tl and s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='tr are the endpoints of the  time interval in s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The g value, h value and f value of state  s are saved in s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='g, s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='h and s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='f, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' A state is termi-  nal state if the state is the optimal final state for the search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  We use ts to save the terminal state and cts to save all can-  didate terminal states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' More specifically, cts saves all closed  states in the vertex a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vc, which is reachable for the agent,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=', tc ≤ s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='tr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In line 1, the individual planning context is  extracted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the current state is invalid, return directly (lines  2-4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In line 5, we update all states’ h value and f value in  OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In line 6, if the TIS states on a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vg have not been  created, create all maximum TIS states and put them into  the OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In lines 7-12, the function StopCheck is used  to check whether the search can stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If yes, build the path  Figure 4: An example to show the process of updating the cost of TIS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The blocks indicate the time interval of the state,  and the number in the block shows the cost to vg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The first row and the second row show the TIS state ([t0, t1], v) and its dummy  son state ([t′  0, t′  1], v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The third row indicates all valid TIS states in v before being updated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The fourth line shows the updated  TIS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The first state cannot be improved, while for the second state, the whole state can be improved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For the third state,  only part of the time interval is covered by [t′  0, t′  1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The state is split into two states, and only the cost of the covered state is  updated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The time interval of the fourth state is not covered, so it is not affected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The grey block shows the improved TIS states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  by the function BuildPath and return directly (We will dis-  cuss the detail of StopCheck and BuildPath later).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Oth-  erwise, the search starts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In each iteration, get the state with  minimum f value in the OPEN (line 14).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the time inter-  val cannot cover any time point after tc, the state is useless  for the current and later searches.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We ignore it and go to the  next iteration of the while loop (lines 15-17).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In lines 18-27,  dummy sons are generated to update the states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In line 29,  we update the OPEN, the CLOSED, and the cts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Finally,  we check whether the search can stop (lines 30-32).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If no,  go to the next iteration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The StopCheck algorithm checks whether the search can  stop and finds the best terminal state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' When finding a better  goal state out of cps is impossible, we stop searching.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' There  are two different scenarios for the stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the agent is in  the scene, the search stops when a state in cps covers tc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Otherwise, the agent can choose a time point to enter the  scene.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Supposed a state ([tl, tr], v) is selected as the terminal  state, the best enter time point is max(tl, tc), and the total  cost from agents’ current TS state (tc, vc) to vertex vg is  max(tl − tc, 0) + gT IS(([tl, tr], v)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the minimum total  cost of choosing a state in cps is less than or equal to the f  value of the current expanded state, no better solution can be  found, and the search can stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The pseudo-code of the StopCheck algorithm is shown  in Algorithm 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In lines 1-3, if there is no element in cts,  the search can not stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In lines 4-10, if the agent is in the  scene, the search can stop only when a state in cts covers tc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In lines 12-18, if the agent is not in the scene, find the state  with minimum total cost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the cost is not higher than the  minimum f value of all nodes in the OPEN, the search can  stop and return the best terminal state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The BuildPath function in Algorithm 3 builds the final  TS state path.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' After getting to the terminal state, we back-  track to get a TIS path.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Based on it, we build the TS path as  the solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Specially, if the agent is not in the scene and the  current time point is earlier than any time point in the termi-  nal state’s time interval, the agent will wait until it reaches  the earliest time point of the target TIS state and then enter  the scene.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Figure 3(d) shows an example of the path build-  ing, selecting ([3, ∞], v1) as the terminal state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  4  Theoretical Analysis  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If hv(v) is admissible and satisfies the con-  sistency assumption, when the first return value of the  StopCheck function is true, it is impossible to have a better  terminal state out of cts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The proof is given in the appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If hv(v) is admissible and satisfies the con-  sistency assumption, the SRISPP algorithm is complete and  optimal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If hv(v) is admissible and satisfies the consistency  assumption, then hT IS(s) is also admissible and satisfies the  consistency assumption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It is proved in the appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  If it is the first planning for the configuration of a and  cons, the OPEN and CLOSED are empty initially.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It is a  standard A*, and the search’s completeness and optimality  are satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  If the OPEN and CLOSED are not empty at the be-  ginning of the search, the state in the CLOSED will not be  reopened, and the g value of the state is already the smallest  cost to the goal vertex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For the state in the OPEN, we up-  date their h value and f value to fit the new situation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The  scenario can be seen starting from a snapshot in the standard  A*, except that some states are closed in advance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' However,  the early closed nodes will not affect the completeness and  optimality of the algorithm because all their unclosed neigh-  bors are in the OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Combining theorem 1 and the above discussions, the the-  orem is proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Corollary 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If hv(v) is admissible and satisfies the consis-  tency assumption, SCBS is complete and optimal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Corollary 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If hv(v) is admissible and satisfies the consis-  tency assumption, SR is complete and snapshot optimal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  These two corollaries can be proved according to the  property of CBS, and RA algorithm (Sharon et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  ˇSvancara et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Because Theorem 2 is proved and the  operations on planning context in SCBS and SR will not af-  fect completeness and optimality, the corollaries are proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  3  4  4-1  5  61  5  :6  4  4  5Algorithm 3: SRSIPP  Input:agent a, constraints cons, current time point tc, indi-  vidual planning context ipc  1: OPEN, CLOSED ← ipc  2: if a is in the scene and (tc, a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vc) ∈ cons then  3:  return false, ipc  4: end if  5: Update h value and f value of states in OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  6: Create maximum TIS states in v′ by cons if the states  are uncreated, and put them into OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  7: fmin ← the smallest f value in OPEN  8: cps ← {([tl, tr], v) ∈ CLOSED|a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='vc = v∧  a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='ts ≤ tr)}  9: stop, ts ← StopCheck(cps, fmin, a) // Algorithm 4  10: if stop then  11:  return BuildPath(ts, a), {OPEN, CLOSED}  12: end if  13: while OPEN is not empty do  14:  s ← the TIS state with minimum f value in OPEN  15:  if s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='tr < tc then  16:  continue  17:  end if  18:  for each vertex v′ in N(s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='v) do  19:  ds ← the dummy son of s in v′  20:  Create maximum TIS states in v′ by cons if the  states are uncreated, and put them into OPEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  21:  for each TIS state s′ in v′ do  22:  if s′ can be improved by ds then  23:  S′  new ← New states after improving s′  24:  OPEN ← OPEN\\{s′} ∪ S′  new  25:  end if  26:  end for  27:  end for  28:  stop, ts ← StopCheck(cps, s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='f, a) // Algorithm 4  29:  Update OPEN, CLOSED and cps by s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  30:  if stop then  31:  return BuildPath(ts, a), {OPEN, CLOSED}  32:  end if  33: end while  5  Experiment  The purpose of our experiments is to evaluate the computa-  tional efficiency of the proposed approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Two 4-neighbor  grid map datasets are used with settings similar to (ˇSvancara  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2019), which is a small grid map dataset and a large  grid map dataset, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We perform online MAPF in  these grid maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Specifically, we move each of the agents  from one cell to another.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' During this period, there will be  new agents starting at any time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  We use success rate and average running time as the met-  rics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The running time limit is 30 seconds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If the algorithm  run exceeds the time limit, the experimental instance is un-  successful and uses the time limit as the running time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We  make statistics based on the number of agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For each  number of agents, it has 100 instances in both datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The experiments assume no agents are in the scene at the  beginning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' On the one hand, the offline parts of algorithms  Algorithm 4: StopCheck  Input: candidate terminal state set cts, the minimum esti-  mated function value in the open list fmin, the agent a  1: if cts is empty then  2:  return false, NULL  3: end if  4: if a is in the scene then  5:  s ← the state which covers tc  6:  if s is NULL then  7:  return false, NULL  8:  else  9:  return true, s  10:  end if  11: else  12:  smin ← argmins∈cts(max(s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='tl − tc, 0) + s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='g)  13:  cmin ← mins∈cts(max(s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='tl − tc, 0) + s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='g)  14:  if cmin ≤ fmin then  15:  return true, smin  16:  else  17:  return false, NULL  18:  end if  19: end if  (a) Small grid maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  (b) Large grid map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Figure 5: Grids for experiments from (ˇSvancara et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  are the same.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' If some instances fail in the offline part, the  online algorithm is not executed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' These test cases are use-  less for comparison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' All randomly generated instances are  always solvable if there are no agents in the scene in the be-  ginning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' On the other hand, all compared methods use iden-  tical offline MAPF solvers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Ignoring it does not affect the  comparison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  We run the algorithms on an AMD R7-5800X CPU with  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='40 GHz and 16GB RAM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Four baselines are selected for  comparison:  RA+CBS+A*(A1): This algorithm uses the Replan All  algorithm to solve the online MAPF problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' When new  agents start, it uses the CBS algorithm to calculate the  multi-agent path plan, whose low-level solver is A*.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  RA+CBS+RSIPP(A2): This algorithm removes all sus-  tainable operations from our proposed approach, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=', all  solvers do not maintain or use the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  SR+SCBS+RSIPP(A3): For this algorithm, the low-  level solver can not reuse the planning context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the  middle-level solver, if the agent strictly follows the pre-  vious path in the node of the conflict tree, the low-level  k  A1  A2  A3  A4  10  96%  96%  96%  96%  12  87%  84%  86%  87%  15  78%  74%  79%  80%  17  65%  63%  63%  64%  20  49%  47%  47%  49%  22  36%  35%  37%  37%  25  27%  26%  28%  29%  Table 1: Table of the success rate in small grids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' k is the  agent number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  k  A1  A2  A3  A4  10  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='68(-)  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='2(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='77)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
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+page_content='98)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
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+page_content='06)  12  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
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+page_content='18)  15  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
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+page_content='53(-)  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='39(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='01)  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='15(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='02)  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='9(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='03)  Table 2: Table of the running time and the speedup ratio  in small grids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The first number in the cell shows the run-  ning time(sec), and the number in parentheses indicates the  speedup relative to A1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' k is the agent number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  solver won’t be called, and a suffix from the results of the  previous planning is used as the results of this planning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  SR+SCBS+SRSIPP(A4): The proposed method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='1  Small Grid Map  In the first dataset, 4 small grid maps are used, as shown  in Figure 5(a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The start and goal points are randomly  sampled in two cells of the opposing sides of the grids,  and the start time point is uniformly sampled from [1, 30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Let k be the number of agents, which is in the range  {10, 12, 15, 17, 20, 22, 25}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In each grid map, we generate  25 experimental instances for each setting of the agent num-  ber.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' For each number of agents, it has 25∗4 = 100 instances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Table 1 shows the result of success rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Except when the  agent number is 17, the success rate of A4 is larger than or  equal to A1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Table 2 shows the running time of all baselines  and the speedup ratio relative to A1 of other baselines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In  the result, A2 did not obtain significant improvement, while  A3 can speed up in most cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The best performance comes  from A4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It shows an improvement in average runtime rela-  tive to A1 under all agent number settings and achieves the  maximum speedup ratio in all baselines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='2  Large Grid Map  In the second dataset, we use the large grid map shown  in Figure 5(b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We generate 100 experimental instances for  each setting of the agent number k in the range of [90, 100].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The start time points are randomly sampled from [1, 100].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  An agent’s start point and goal point are sampled from two  different sides.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Table 3 and Table 4 show the result of the success rate,  the average running time, and the speedup ratio relative to  A1 of different baselines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' A2 and A3 perform better than A1  k  A1  A2  A3  A4  90  84%  85%  88%  91%  92  82%  84%  86%  89%  94  90%  89%  91%  92%  96  75%  77%  81%  84%  98  72%  76%  82%  83%  100  54%  69%  72%  77%  Table 3: Table of the success rate in large grids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' k is the agent  number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  k  A1  A2  A3  A4  90  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='09(-)  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='98(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='12)  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='48(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='35)  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='06(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='67)  92  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='69(-)  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='61(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='01)  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='13(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='19)  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='8(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='43)  94  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='04(-)  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='27(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='97)  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='59(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='22)  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='52(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='46)  96  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='05(-)  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='35(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='98)  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='25(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='16)  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='84(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='33)  98  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='37(-)  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='4(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='08)  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='5(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='27)  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='21(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='45)  100  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='06(-)  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='78(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='22)  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='02(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='39)  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='58(1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='56)  Table 4: Table of the running time and the speedup ratio  in large grids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The first number in the cell shows the run-  ning time(sec), and the number in parentheses indicates the  speedup relative to A1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' k is the agent number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  in most cases, while A4 runs the fastest among all methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In all instances, the average speedup ratio of A4 relative to  A1 reaches 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  The running time of 92 and 94 agents are shorter than  90 agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It is because when the number of agents is large,  the running time is not significantly influenced by the small  increment of the agent number but is dominated by some  hard-to-solve cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='3  Discussion  The improvement in the large grids is more obvious than in  the small grids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We believe it is because of the path length.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In the small grid maps, the path of agents is short.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Sustain-  able information can only be used a few times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In the large  map, the path is much longer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Sustainable information is  used more frequently, making A4 get a higher speedup ratio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  6  Conclusion  We proposed a three-level algorithm to solve the online  MAPF problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Three levels are responsible for simulating  the multi-agent online environment, solving the multi-agent  path planning, and using the historical planning informa-  tion to assist in solving the single-agent path planning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' We  proved the completeness and the snapshot optimality of our  approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' The experiment shows that our proposed method  runs faster than the SOTA algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' During the experiment,  we also found that the performance in large grids is much  better than in small grids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' This is because the agent has a  longer path in a larger grid so that the planning context can  be reused more times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' It shows that the longer the path, the  better the acceleration effect of our method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  In the future, more aspects of using sustainable informa-  tion, such as building the conflict tree, will be explored to  improve the efficiency of the algorithm further.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  References  Choudhury, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Solovey, K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Kochenderfer, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' and Pavone,  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Coordinated Multi-Agent Pathfinding for Drones  and Trucks over Road Networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In Proceedings of the 21st  International Conference on Autonomous Agents and Multi-  agent Systems, 272–280.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Hart, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Nilsson, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
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+page_content=' Co-  ordinating hundreds of cooperative, autonomous vehicles in  warehouses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' AI magazine, 29(1): 9–9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content='  Yu, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' and LaValle, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' 2013.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' Structure and intractability  of optimal multi-robot path planning on graphs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
+page_content=' In Twenty-  Seventh AAAI Conference on Artificial Intelligence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/BdE3T4oBgHgl3EQfUAoU/content/2301.04446v1.pdf'}
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+Color Me Intrigued: Quantifying Usage of Colors in Fiction
+Siyan Li
+Stanford University
+siyanli@stanford.edu
+Abstract
+We present preliminary results in quantitative analyses of
+color usage in selected authors’ works from LitBank. Using
+Glasgow Norms, human ratings on 5000+ words, we measure
+attributes of nouns dependent on color terms. Early results
+demonstrate a significant increase in noun concreteness over
+time. We also propose future research directions for compu-
+tational literary color analytics. 1
+1
+Introduction
+All great writers are great colourists, Virginia Woolf once
+stated (Woolf 1934). Analyzing colors in literary work
+across time and authors has fascinated the field of literature,
+philosophy, and psychology (Skard 1946).
+Most literary analyses of colors focus on only one author,
+one work, or one historical era. There has been very few
+large-scale analyses of color usage shifts. Recently, natural
+language processing (NLP) has progressed in fields poten-
+tially relevant to literary color analyses, such as dependency
+parsing (Qi et al. 2020) and named entity recognition (Li
+et al. 2020). Leveraging these tools expedites localization of
+spans of interest, increasing efficiency and ease of larger-
+scale literary analyses.
+What makes literary color analyses interesting for nat-
+ural language processing? Authors utilize colors in nu-
+merous ways, and NLP tools should capture this variety.
+While Goethe uses colors as a backdrop of his narratives,
+only using them to emphasize the plastic shapes of objects
+(Bruns 1928), Dante’s coloring in his Divine Comedy dis-
+plays more symbolic undertones. The colors on the three
+faces of Dante’s Lucifer can be related to the three horses
+of the Apocalypse (Skard 1946). The sudden absence of
+green in Heavenly Paradise may stem from green’s associ-
+ation with hope, and Dante’s Paradise eliminates the need
+for hope since it fulfills all wishes (Austin 1933). In con-
+trast, James Joyce’s green can be interpreted to symbolize
+absinthe (Earle 2003) and the author’s frustration with the
+Irish Catholic Church (Xie 2015). For more contemporary
+Copyright © 2023, Association for the Advancement of Artificial
+Intelligence (www.aaai.org). All rights reserved.
+1All code and data used are available at https://github.com/
+siyan-sylvia-li/ColorLit.
+writers, Virginia Woolf’s blue in To the Lighthouse accom-
+panies Mrs. Ramsay for her Madonna role and her mix-
+ture of radiance and somberness (Stewart 1985). The same
+blue manifests cholera and illness in Edgar Allan Poe’s The
+Masque of the Red Death (Yoon 2021). Despite some sub-
+jectivity in these interpretations, the existence of differences
+in color usages are absolute. We want to examine whether
+current NLP tools “understand” these differences.
+We propose a novel line of research using word embed-
+dings and pre-trained language models to quantify color us-
+ages in literature. Specifically, we measure the attributes of
+nouns dependent on color adjectives according to the Glas-
+gow Norms (Scott et al. 2019). Preliminary results demon-
+strate statistically significant trends over time for certain col-
+ors’ Glasgow Norm attributes. We present future research
+directions and plausible experiments.
+Our proposed framework can supplement literary color
+analyses research and provide additional insight for color
+usages comparisons. Looking at literature and creativity
+through the lens of colors is informative because of the
+prevalence of color terms in literature. Color terms can serve
+as anchoring points of comparison between authors, and po-
+tentially between humans and language models.
+2
+Related Work
+The most similar work to ours would be Rabinovich and
+Carmeli (2022), a study of color term usage by both non-
+color-blind and color-blind individuals on Reddit. The au-
+thors discover significant differences in certain color terms.
+They then concentrate on the nouns that are modified by
+color words, using dependency parsing to obtain NOUN
+words in an AMOD dependency pair with an ADJ color
+term. The authors identify significant discrepancies between
+the two populations in imageability (Scott et al. 2019) values
+of color-modified nouns. Our preliminary work is method-
+ologically similar, but we study literature instead. Addition-
+ally, our work more extensively leverages labels from the
+Glasgow Norms by using three dimensions instead of one.
+Word embeddings play a crucial role in computational
+social science. Garg et al. (2018) leverages Word2vec
+(Mikolov et al. 2013) to reflect changes in relationships be-
+tween the embedding representing women and different ad-
+jectives as potentially a result of the feminist movement. A
+similar work, Bailey, Williams, and Cimpian (2022), show-
+arXiv:2301.03559v1  [cs.CL]  9 Jan 2023
+
+cases that people = man by comparing distances be-
+tween word embeddings of trait words of people, men, and
+women respectively. We are interested in similar techniques
+in a literary color analysis context.
+3
+Dataset
+We use LitBank (Bamman, Popat, and Shen 2019), a Euro-
+centric collection of 100 English fictions from 75 authors.
+We conduct a scrape of Project Gutenberg using LitBank’s
+Gutenberg ID’s to obtain the full text of each work. The gen-
+res consist primarily of realistic novels, with few exceptions
+of science fiction (H.G. Wells, Mary Shelley), fantasy (Bram
+Stoker, Oscar Wilde), and horror (Edgar Allan Poe).
+4
+Methodology
+4.1
+Extracting Modified Nouns
+Colors and Synonyms
+We select common colors and cu-
+rate a list of their synonyms. The colors include “red”,
+“green”, “black”, “white”, “blue”, “brown”, “gray”, “yel-
+low”, “pink”, and “purple”. All color terms and their syn-
+onyms are in Appendix A. Each set of sentences from a
+Project Gutenberg E-book are split into lemmatized words.
+We choose sentences containing either our specified color
+adjectives or their synonyms for dependency parsing.
+Dependency Parsing
+Although Rabinovich and Carmeli
+(2022) strictly studies nouns modified by color terms
+through the AMOD dependency, this would be limiting in
+lyrical writing. For instance, “she has eyes of sapphire” de-
+scribes blue eyes and should be included in our analysis, but
+dependency parsing would categorize “eyes” and “saphire”
+to linked by NMOD instead of AMOD. Therefore, we ex-
+pand upon our pool of nouns by including all nouns with
+a dependency link to our color terms. We employ Stanza’s
+Dependency Parser (Qi et al. 2020). Upon obtaining depen-
+dencies on a sentence, we perform a filtering process to re-
+tain the relevant head-dependent pairs. The specific filter-
+ing process is as follows. For each head-dependent pair:
+(1) Lemmatize both the head and the dependent. (2) Iter-
+ate through all color words and their synonyms; if none of
+them is present in either the head or the dependent, prune
+out this pair. (3) If the other word in the dependency pair is
+not a noun or a proper noun, prune out this pair.
+4.2
+Glasgow Norm Models
+The Glasgow Norms are a list of 5,553 words with corre-
+sponding normative human ratings on different psycholin-
+guistic dimensions. Our ongoing work concentrates on: (1)
+Imageability (IMAG), the ease of summoning a mental im-
+age from a word; (2) Concreteness (CNC), the extent to
+which words can be experienced to our senses; and (3) Va-
+lence (VAL), how positive or negative a word’s value is. We
+hypothesize that different authors differ on the imageabili-
+ty/concreteness/valence values of color-dependent nouns.
+Although the Glasgow Norms vocabulary is extensive,
+we still hope to handle unseen words. FastText embeddings
+(Joulin et al. 2016) reduced to 100 dimensions are used to
+train separate 1-layer Multi-Layer Perceptron (MLP) models
+Color
+# of Occurrences
+Color
+# of Occurrences
+red
+2888
+green
+1839
+black
+3325
+white
+4990
+blue
+1622
+brown
+1206
+gray
+1575
+yellow
+848
+pink
+648
+purple
+545
+Table 1: The total numbers of occurrences of our selected
+color terms in the 100 LitBank novels. These are instances
+where the color terms act as either a dependent or a depen-
+dency head.
+to predict these values. We choose FastText for its adaptabil-
+ity for unseen words. Prior to training, all scores are normal-
+ized to the 0 to 1 range for better interpretability, consistent
+with Rabinovich and Carmeli (2022). Three neural networks
+with sigmoid activations are trained on these data, and eval-
+uated on a held-out test set with an 8:1:1 split. We use Pear-
+son’s correlation between predictions and ground truths as
+our metric. Rabinovich and Carmeli (2022) reports a Pear-
+son’s correlation of 0.76 for their IMAG model on a random
+held-out set, while ours achieves 0.79 on the test set. We un-
+derstand that the held-out test set may be different, but this
+indicates that our IMAG model should as potent as the prior
+model. Our CNC model and VAL model achieve correlation
+scores of 0.83 and 0.76, respectively.
+To prevent repeated occurrences of a word affecting the
+average Glasgow Norm values, the dependent nouns are
+deduplicated when computing the averages.
+5
+Preliminary Results
+Despite our analyses on LitBank yield statistically signifi-
+cant results when analyzed across time, this could stem from
+an imbalance in the distribution of publication time in Lit-
+Bank. This paper aims to establish a preliminary framework
+for studying color usages in literature, and current results
+would need corroboration from additional texts from differ-
+ent eras and genres.
+5.1
+Color-dependent Nouns
+We conduct both quantitative and qualitative analyses on
+color-dependent nouns in LitBank through both comput-
+ing average Glasgow Norm values and through inspection
+of most frequently associated nouns. Additional analyses of
+color term frequencies are in Appendix B.
+Out of all unique nouns, 1299 are within the Glas-
+gow Norm vocabulary, and 1924 are OOV. We use our
+trained MLPs to infer Glasgow Norm scales of the out-
+of-vocabulary nouns. After recognizing an upward trend in
+IMAG and CNC, we compute Pearson’s correlations be-
+tween publication year and average IMAG and CNC val-
+ues for all color terms in novels where the color is present
+(Table 2, Figure 1). The IMG and CNC values increase sig-
+nificantly over time for black, white, yellow, and pink. This
+indicates that the nouns associated with these color terms
+
+Figure 1: Imageability plots for the color terms with signif-
+icant results. We omit the concreteness plots here because
+IMAG and CNC are highly correlated, but we provide the
+full set of plots in Appendix C.
+become increasingly concrete easier to conjure mental im-
+ages of. This is consistent with some conclusions from Skard
+(1946) that early color usages are obscure and abstract.
+Nouns in Individual Works
+We observe interesting data
+points in our plots (the full sets of figures are available in
+Appendix C). For instance, we notice a significantly lower
+valence for red in Edgar Allan Poe’s The Masque of the
+Red Death, because the only nouns associated with red are
+“death”, “stain”, and “horror”. Similarly, an abnormally low
+green valence arises in Henry Fielding’s History of Tom
+Jones, a Foundling, because green is attached to “slut”,
+“witch”, and “monster”.
+Nouns over Publication Time
+We divide our fictions into
+pre-1800’s, 1800 - 1900, and post-1900 based on patterns
+in our data. We then deduplicate dependent nouns in each
+work so that we can measure most frequent nouns in each
+era without thematic motifs biasing our analyses. A list of
+selected color terms and their most dependent nouns in each
+of the eras are in Table 3.
+From the table we observe a significant shift in frequently
+used nouns across time. Pre-1800 dependent nouns are more
+abstract and complex compared to post-1800 nouns depen-
+dent on the same colors, while there is no significant differ-
+ence between 1800 - 1900 and post-1900. This is a possible
+explanation for the increase in imageability and concrete-
+ness over time among LitBank works.
+5.2
+Inter-Author Differences
+We plot the Word2vec embeddings of nouns dependent on
+the same colors from different authors to decipher how
+the color terms are used. Out-of-vocabulary nouns are dis-
+carded. This serves as a crude visualization of different top-
+ics associated with these color terms. For instance, when
+comparing nouns modified by yellow in works of Fitzger-
+ald and Joyce in LitBank, the topic of facial hair (hair, beard,
+IMAG Results
+Color
+Pearson’s r
+Color
+Pearson’s r
+red
+-0.095*
+green
+0.059
+black
+0.257**
+white
+0.303***
+pink
+0.534***
+yellow
+0.340**
+CNC Results
+Color
+Pearson’s r
+Color
+Pearson’s r
+black
+0.237**
+white
+0.239**
+pink
+0.517***
+yellow
+0.318***
+VAL Results
+Color
+Pearson’s r
+Color
+Pearson’s r
+green
+0.273***
+purple
+0.210*
+Table 2: Pearson’s correlations between published years and
+Glasgow Norm values of the 100 fictions for color terms
+with sig. results. *** p < 0.001, ** p < 0.05, and * p < 0.1.
+Full results are in Appendix C.
+Color
+Era
+Frequent Nouns
+pink
+Pre-1800
+shame, guilt, folly,
+ribbon, indignation
+1800 - 1900
+cheek, face, ribbon, rose, lip
+Post-1900
+cheek, face, rose, paper, bud
+black
+Pre-1800
+color, eye, grain, hair, wave
+1800 - 1900
+hair, eye, shadow, dress, face
+Post-1900
+hair, eye, dress, figure, man
+white
+Pre-1800
+face, cheek, countenance,
+cliff, cave
+1800 - 1900
+face, cheek, hand, hair, man
+Post-1900
+face, hand, eye, hair, man
+yellow
+Pre-1800
+appearance, complexion,
+blossom, lustre, mist
+1800 - 1900
+hair, light, face, glove, skin
+Post-1900
+hair, light, eye, flower, house
+Table 3: Most frequently color-modified nouns from each
+era for selected color terms. Example sentences are in Ap-
+pendix D
+pompadour) only manifests in Fitzgerald’s, while food items
+(soup, cheese) appear in Joyce’s. Additional examples are in
+Appendix D.
+6
+Proposal of Future Work
+6.1
+Further Analyses
+Fine-grained Timeline Analyses
+Similar to Garg et al.
+(2018), we can train separate Word2vec models on each
+decade of literature in our collection for fine-grained anal-
+yses. Preliminary results indicate that certain colors become
+
+black
+0.9
+IMAG
+0.8
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearwhite
+0.9
+0.8
+IMAG
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearyellow
+1.0
+0.8
+IMAG
+0.6
+0.4
+1750
+1800
+1850
+1900
+Yearpink
+0.8
+IMAG
+0.6
+0.4
+0.2
+1750
+1800
+1850
+1900
+YearFigure 2: Word2vec embeddings of nouns modified by yel-
+low in novels by F. Scott Fitzgerald (red points) and James
+Joyce (blue points).
+increasingly associated with concrete descriptions (pink as-
+sociated with cheeks and face). We can compute cosine sim-
+ilarities between Word2vec embeddings of certain colors
+with words such as “face” and “lips”; this should increase
+over time as we observe increasing presence of colors in
+character descriptions. A similar metric can further quantize
+inter-author differences as well.
+Additional Clustering
+We demonstrate the prowess of
+Word2vec for visualizing color-related topics in this pro-
+posal, but word embeddings fail to account for contexts.
+Further clustering analyses can include embeddings from
+context-dependent pre-trained language models such as Sen-
+tenceBERT (Reimers and Gurevych 2019) and BERT (De-
+vlin et al. 2018).
+6.2
+RQs: From a Literature Perspective
+How do colors differ across genres?
+We chose LitBank
+for its ease of access and thorough documentations, but one
+emerging issue is that LitBank skews heavily towards re-
+alistic fictions. Due to this imbalance, we cannot compare
+color usages meaningfully across genres. We will include
+more books in future analyses. If we observe significant dif-
+ferences in frequencies of different color words or in the
+concepts and objects associated with the colors, we can con-
+clude that there exists cross-genre differences in color usage.
+We already observe such differences. Bram Stoker’s
+Dracula (Stoker 1897), a pioneering work in vampire liter-
+ature, features numerous descriptions of pale maidens with
+their red lips, as well as of scarlet blood and crimson eyes.
+Therefore, we notice much more frequent usage of the color
+red in this work, compared to H. G. Wells’s The War of the
+Worlds (Wells 1897), where red most commonly modifies
+weeds. We want to inspect whether the same general pattern
+would persist on larger-scale analyses.
+How do colors differ across literary forms?
+Literary
+color analyses often separate novelists and poets. Compar-
+isons are often drawn only between two poets or two nov-
+elists, but rarely both. Our hypothesis is that colors usage
+in poetry differs significantly from color usage in prose and
+novels. Such differences can manifest as a discrepancy in
+concreteness (e.g. in poetry, colors can more often associate
+with a concept instead of a concrete object). Expanding our
+research to include poets, preferably those contemporary to
+our novelists, should enable us to address this systematically.
+6.3
+RQs: From a Social Science Perspective
+How do colors differ across cultures and classes?
+Dif-
+ferent cultures can have different associations with the same
+color; for instance, white is often a symbol of purity and a
+staple at Western weddings, whereas the same color is used
+more traditionally in Chinese funerals. These associations
+may reflect socio-economic classes as well (e.g. white-collar
+and blue-collar jobs) through colors frequently co-occurring
+with characters from different cultures and societal classes.
+To analyze this, we will utilize named entity recognition to
+link colors to characters, operating with more context. Pur-
+suing this research direction would involve translated work,
+instead of using only Euro-centric collections of literature.
+The social class of a character can either be looked up on-
+line or inferred by a model to automate the process. We can
+then cluster character colors by cultures and classes.
+How do colors affect biases and stereotypes?
+Current-
+day color associations, such as pink with girls and blue with
+boys, can fuel biases. For instance, boys who enjoy wearing
+pink may be regarded as “girly” and overly feminine. Cer-
+tain colors also contain associations with LGBTQ+ commu-
+nities. We are interested in identifying how these color-based
+biases (going beyond race) manifest in literature and online
+communities. We can study this by finding colors associated
+with characters of a demographic group of interest. Tracing
+through past literature may also shed light upon the evolu-
+tion of color associations.
+7
+Discussion
+Our work serves as a step towards more systematic analy-
+ses of color usages in literature using natural language pro-
+cessing tools. Following prior work, we propose using The
+Glasgow Norms and word embeddings as tools for quan-
+tifying color usage differences. We demonstrate significant
+increasing trends in imageability and concreteness in color-
+dependent nouns over time.
+One limitation is the range of language we are capable of
+handling is constrained by the language models we employ.
+Our current collection does not have many pre-1800 pieces.
+While it is possible to increase the representation of pre-
+1800s literature, the domain shift in English style and word
+conventions may require different word embedding and pre-
+trained models to embed narratives (e.g. Chaucer often uses
+“red” in place of “read”, standard of his time, but causes am-
+biguity when processing texts on a large scale). Given such
+shifts in vocabulary and sentence structures, we may fail to
+provide meaningful insights into earlier literature, since the
+word embeddings may have disjoint vocabularies, and mod-
+els such as SentenceBERT are trained on more modern texts.
+
+yellow
+bhaird
+pompadour
+4 
+2
+wax
+0
+sheet
+square
+tiewh
+streak
+journal
+knee
+gingry
+boot
+sol
+dadchild
+-2
+dwaistebtnd
+cap
+itaivgri
+reflestiartle
+-4
+sobbing
+twilight
+Jight
+sun
+gw
+jnsoence
+paese
+Mkeen
+melon
+-6
+flower
+2
+3
+5
+6
+7
+8
+9
+4References
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+preprint arXiv:1908.10084.
+Scott, G. G.; Keitel, A.; Becirspahic, M.; Yao, B.; and
+Sereno, S. C. 2019. The Glasgow Norms: Ratings of 5,500
+words on nine scales. Behavior research methods, 51(3):
+1258–1270.
+Skard, S. 1946. The Use of Color in Literature: A Survey
+of Research.
+Proceedings of the American Philosophical
+Society, 90(3): 163–249.
+Stewart, J. F. 1985. Color in To the Lighthouse. Twentieth
+Century Literature, 31(4): 438–458. Publisher: [Duke Uni-
+versity Press, Hofstra University].
+Stoker, B. 1897. Dracula: 1897.
+Wells, H. G. 1897. The war of the worlds. Broadview Press.
+Color Word
+Synonyms
+red
+cardinal, coral, crimson, maroon,
+burgundy, flaming, scarlet, fuchsia
+green
+emerald, olive, aquamarine, beryl,
+jade, lime
+black
+ebony, jet, obsidian, onyx, inky
+white
+alabaster, ashen, blanched, bleached,
+cadaverous, doughy, pale, pallid,
+pasty, ivory, pearly, beige
+blue
+azure, indigo, sapphire, cerulean,
+cobalt, turquoise, teal
+brown
+amber, khaki, tan, umber, hazel
+gray
+grey
+yellow
+N/A
+pink
+rosy, blush, magenta
+purple
+lavender, lilac, mauve, periwinkle,
+plum, violet, amethyst
+Table 4: List of color words used and their synonyms
+Woolf, V. 1934. Walter Sickert: A Conversation. L. and
+Virginia Woolf at the Hogarth Press.
+Xie, Y. 2015. Color as Metaphor-A Study of Joyce’s Use of”
+Black” and” Green” in Dubliners and A Portrait of the Artist
+as a Young Man. English Language and Literature Studies,
+5(4): 61.
+Yoon, S. 2021. Color Symbolisms of Diseases: Edgar Al-
+lan Poe’s “The Masque of the Red Death”. The Explicator,
+79(1-2): 21–24.
+A
+Color terms and their synonyms used
+We list the color terms used in this work, along with their
+corresponding synonyms obtained through manual inspec-
+tion on Thesaurus.com entries, in Table 4.
+B
+Normalized Frequencies Over Time
+After filtering through sentences in LitBank for relevant de-
+pendence pairs, the absolute frequencies of each color term
+are listed in Table 1. We also calculate the normalized fre-
+quencies (absolute frequency divided by the total number of
+words) for the 100 fictions. We notice an increasing trend in
+the normalized frequencies over time for LitBank, and com-
+pute Pearson’s correlations between normalized frequencies
+of color terms and time to verify this trend (Table 5).
+We present the scatter plots of normalized frequencies in
+Figure 3.
+C
+Glasgow Norm Plots of Modified Nouns
+Over Time
+The plots corresponding to how color-modified nouns
+change over time with respect to their Glasgow Norm
+
+Color
+Pearson’s r
+Color
+Pearson’s r
+red
+0.173*
+green
+0.134
+black
+0.139
+white
+0.168*
+blue
+0.148
+brown
+0.202**
+gray
+0.162
+yellow
+0.184*
+pink
+0.173*
+purple
+0.150
+Table 5: Pearson’s correlations between published years and
+normalized frequencies of the 100 fictions for each color
+term. ** indicates p < 0.05, and * p < 0.1.
+IMAG, CNC, and VAL values are presented here in Fig-
+ures 4, 5, and 6. We also include the full list of Pearson
+correlation results for all color terms in Table 6.
+IMAG Results
+Color
+Pearson’s r
+Color
+Pearson’s r
+red
+-0.095*
+green
+0.059
+black
+0.257**
+white
+0.303***
+blue
+-0.163
+brown
+0.129
+gray
+-0.081
+yellow
+0.340**
+pink
+0.534***
+purple
+0.162
+CNC Results
+Color
+Pearson’s r
+Color
+Pearson’s r
+red
+-0.054
+green
+0.160
+black
+0.237**
+white
+0.239**
+blue
+-0.133
+brown
+0.175
+gray
+-0.044
+yellow
+0.318***
+pink
+0.517***
+purple
+0.055
+VAL Results
+Color
+Pearson’s r
+Color
+Pearson’s r
+red
+-0.025
+green
+0.273***
+black
+0.059
+white
+0.161
+blue
+-0.104
+brown
+-0.148
+gray
+0.072
+yellow
+-0.01
+pink
+0.081
+purple
+0.210*
+Table 6: Full list of Pearson’s correlations between published
+years and Glasgow Norm values of the 100 fictions for each
+color term. *** p < 0.001, ** p < 0.05, and * p < 0.1.
+D
+Example of Color Term Usages
+In the following usage examples, the color terms are un-
+derlined, bolded and colored, while the dependent noun is
+bolded.
+D.1
+Pink
+HENRY FIELDING, 1749
+Adorned with all the charms in which nature can array
+her; bedecked with beauty, youth, sprightliness, innocence,
+modesty, and tenderness, breathing sweetness from her rosy
+lips, and darting brightness from her sparkling eyes, the
+lovely Sophia comes!
+FANNY BURNEY, 1778
+We were sitting in this manner, he conversing with all
+gaiety, I looking down with all foolishness, when that fop
+who had first asked me to dance, [...] I interrupted him I
+blush for my folly, with laughing; yet I could not help it;
+for, added to the man’s stately foppishness, [...] that I could
+not for my life preserve my gravity.
+ANN WARD RADCLIFFE, 1794
+As they descended, they saw at a distance, on the right,
+one of the grand passes of the Pyrenees into Spain, gleaming
+with its battlements and towers to the splendour of the set-
+ting rays, yellow tops of woods colouring the steeps below,
+while far above aspired the snowy points of the mountains,
+still reflecting a rosy hue.
+Conscious innocence could not prevent a blush from
+stealing over Emily’s cheek; she trembled, and looked con-
+fusedly under the bold eye of Madame Cheron, who blushed
+also; but hers was the blush of triumph, such as sometimes
+stains the countenance of a person, congratulating himself
+on the penetration which had taught him to suspect another,
+and who loses both pity for the supposed criminal, and
+indignation of his guilt, in the gratification of his own vanity
+CHARLOTTE BRONTE, 1847
+Her beauty, her pink cheeks and golden curls, seemed to
+give delight to all who looked at her, and to purchase indem-
+nity for every fault.
+Its garden, too, glowed with flowers: hollyhocks had
+sprung up tall as trees, lilies had opened, tulips and roses
+were in bloom; the borders of the little beds were gay with
+pink thrift and crimson double daisies; the sweetbriars gave
+out, morning and evening, their scent of spice and apples;
+and these fragrant treasures were all useless for most of the
+inmates of Lowood, except to furnish now and then a hand-
+ful of herbs and blossoms to put in a coffin.
+She pulled out of her box, about ten minutes ago, a
+little pink silk frock; rapture lit her face as she unfolded
+it; coquetry runs in her blood, blends with her brains, and
+seasons the marrow of her bones.
+ARTHUR CONAN DOYLE, 1892
+That trick of staining the fishes’ scales of a delicate pink
+is quite peculiar to China.
+Her violet eyes shining, her lips parted, a pink flush upon
+her cheeks, all thought of her natural reserve lost in her over-
+powering excitement and concern.
+As we approached, the door flew open, and a little blonde
+woman stood in the opening, clad in some sort of light
+
+Figure 3: Log-scale scatter plots of normalized color term frequencies for each publication in LitBank.
+
+blue
+103
+Frequency (x 1E-5)
+102
+101
+100
+1750
+1800
+1850
+1900
+Yearbrown
+Frequency (x 1E-5)
+102
+101
+100
+1750
+1800
+1850
+1900
+Yeargray
+103
+Frequency (x 1E-5)
+102
+101
+100
+1750
+1800
+1850
+1900
+Yearyellow
+Frequency (x 1E-5)
+102
+101
+100
+1750
+1800
+1850
+1900
+Yearpink
+102
+Frequency (x 1E-5)
+101
+100
+1750
+1800
+1850
+1900
+Yearpurple
+102
+Frequency (x 1E-5)
+101
+100
+1750
+1800
+1850
+1900
+Yearred
+Frequency (x 1E-5)
+102
+101
+100
+1750
+1800
+1850
+1900
+Yeargreen
+Frequency (x 1E-5)
+102
+101
+100
+1750
+1800
+1850
+1900
+Yearblack
+103
+LE-5)
+1
+X
+102
+Fregquency
+101
+1750
+1800
+1850
+1900
+Yearwhite
+103
+1E-5)
+Frequency (x 1
+102
+101
+1750
+1800
+1850
+1900
+YearFigure 4: IMAG scatter plots of nouns modified by color terms for each publication in LitBank.
+
+black
+0.9
+IMAG
+0.8
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearred
+0.9
+IMAG
+0.8
+0.7
+0.6
+1750
+1850
+1800
+1900
+Yeargreen
+0.9
+0.8
+IMAG
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+Yearblue
+1.0
+0.9
+IMAG
+0.8
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearbrown
+0.9
+0.8
+IMAG
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+Yearwhite
+0.9
+0.8
+IMAG
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yeargray
+0.9
+IMAG
+0.8
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearpurple
+1.0
+0.8
+IMAG
+0.6
+0.4
+1750
+1800
+1850
+1900
+Yearyellow
+1.0
+0.8
+IMAG
+0.6
+0.4
+1750
+1800
+1850
+1900
+Yearpink
+0.8
+IMAG
+0.6
+0.4
+0.2
+1750
+1800
+1850
+1900
+YearFigure 5: CNC scatter plots of nouns modified by color terms for each publication in LitBank.
+
+red
+0.9
+0.8
+CNC
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+Yeargreen
+0.9
+0.8
+CNC
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+Yearblack
+1.0
+0.9
+CNC
+0.8
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearwhite
+0.8
+CNC
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearblue
+0.9
+0.8
+CNC
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+Yearbrown
+0.9
+0.8
+CNC
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+Yeargray
+0.9
+0.8
+CNC
+0.7
+0.6
+1750
+1800
+1850
+1900
+Yearyellow
+1.0
+0.8
+CNC
+0.6
+0.4
+0.2
+1750
+1800
+1850
+1900
+Yearpink
+0.8
+0.4
+1750
+1800
+1850
+1900
+Yearpurple
+0.9
+0.8
+CNC
+0.7
+0.6
+0.5
+1750
+1800
+1850
+1900
+YearFigure 6: VAL scatter plots of nouns modified by color terms for each publication in LitBank.
+
+red
+0.7
+0.6
+0.5
+VAL
+0.4
+0.3
+0.2-
+1750
+1800
+1850
+1900
+Yeargreen
+0.8
+0.7
+0.6
+VAL
+0.5
+0.4
+0.3
+1750
+1800
+1850
+1900
+Yearblack
+0.8
+0.7
+≤0.6
+0.5
+1750 1800
+1850
+1900
+Yearwhite
+0.7.
+M0.6
+0.5
+1750
+1800
+1850
+1900
+Yearblue
+0.7
+M0.6
+0.5
+1750
+1800
+1850
+1900
+Yearbrown
+0.7
+0.5
+1750
+1800
+1850
+1900
+Yeargray
+0.70
+0.65
+0.55
+0.50
+1750
+1800
+1850
+1900
+Yearyellow
+0.7
+0.6
+0.5
+VAL
+0.4
+0.3
+0.2
+1750
+1800
+1850
+1900
+Yearpink
+0.8
+0.7
+≤0.6
+0.5
+0.4
+1750
+1800
+1850
+1900
+Yearpurple
+0.8
+0.6
+VAL
+0.4
+0.2
+1750
+1800
+1850
+1900
+Yearmousseline de soie, with a touch of fluffy pink chiffon at
+her neck and wrists.
+H.G. WELLS, 1897
+It was the fact that all his forehead above his blue glasses
+was covered by a white bandage, and that another covered
+his ears, leaving not a scrap of his face exposed excepting
+only his pink, peaked nose.
+P. G. WODEHOUSE, 1919
+Jimmy turned into that drug store at the top of the Hay-
+market at which so many Londoners have found healing and
+comfort on the morning after, and bought the pink drink for
+which his system had been craving since he rose from bed.
+The clerk had finished writing the ticket, and was pressing
+labels and a pink paper on him.
+F. SCOTT FITZGERALD, 1920:
+Myra sprang up, her cheeks pink with bruised vanity, the
+great bow on the back of her head trembling sympathetically.
+D.2
+White
+FANNY BURNEY, 1778
+She told her niece, that she had been indulging in fanciful
+sorrows, and begged she would have more regard for deco-
+rum, than to let the world see that she could not renounce an
+improper attachment; at which Emily’s pale cheek became
+flushed with crimson, but it was the blush of pride, and she
+made no answer.
+MARY WOLLSTONECRAFT, 1788
+Henry started at the sight of her altered appearance; the
+day before her complexion had been of the most pallid hue;
+but now her cheeks were flushed, and her eyes enlivened
+with a false vivacity, an unusual fire.
+JANE AUSTEN, 1813
+Her pale face and impetuous manner made him start, and
+before he could recover himself to speak, she, in whose mind
+every idea was superseded by Lydia’s situation, hastily ex-
+claimed, “I beg your pardon, but I must leave you.
+From his garden, Mr. Collins would have led them round
+his two meadows; but the ladies, not having shoes to en-
+counter the remains of a white frost, turned back
+ELIZABETH CLEGHORN GASKELL, 1855
+She lay curled up on the sofa in the back drawing room in
+Harley Street looking very lovely in her white muslin and
+blue ribbons.
+She found out that the water in the urn was cold, and or-
+dered up the great kitchen tea kettle; the only consequence
+of which was that when she met it at the door, and tried to
+carry it in, it was too heavy for her, and she came in pouting,
+with a black mark on her muslin gown, and a little round
+white hand indented by the handle, which she took to show
+to Captain Lennox, just like a hurt child, and, of course, the
+remedy was the same in both cases.
+But he had the same large, soft eyes as his daughter, eyes
+which moved slowly and almost grandly round in their or-
+bits, and were well veiled by their transparent white eyelids.
+CHARLES DICKENS, 1861
+I lighted my fire, which burnt with a raw pale flare at that
+time of the morning, and fell into a doze before it.
+She’s all in white,’ he says, ‘wi’ white flowers in her hair,
+and she’s awful mad, and she’s got a shroud hanging over her
+arm, and she says she’ll put it on me at five in the morning.’
+When we was put in the dock, I noticed first of all what
+a gentleman Compeyson looked, wi’ his curly hair and his
+black clothes and his white pocket handkercher, and what
+a common sort of a wretch I looked.
+ELIZABETH VON ARNIM, 1898
+There are so many bird cherries round me, great trees with
+branches sweeping the grass, and they are so wreathed just
+now with white blossoms and tenderest green that the gar-
+den looks like a wedding.
+When that time came, and when, before it was over, the
+acacias all blossomed too, and four great clumps of pale, sil-
+very pink peonies flowered under the south windows, I felt
+so absolutely happy, and blest, and thankful, and grateful,
+that I really cannot describe it.
+D.3
+Black
+JONATHAN SWIFT, 1726
+In his right waistcoat pocket we found a prodigious bun-
+dle of white thin substances, folded one over another, about
+the bigness of three men, tied with a strong cable, and
+marked with black figures; which we humbly conceive to
+be writings, every letter almost half as large as the palm of
+our hands.
+In the left pocket were two black pillars irregularly
+shaped: we could not, without difficulty, reach the top of
+them, as we stood at the bottom of his pocket.
+In one of these cells were several globes, or balls, of a
+most ponderous metal, about the bigness of our heads, and
+requiring a strong hand to lift them: the other cell contained a
+heap of certain black grains, but of no great bulk or weight,
+for we could hold above fifty of them in the palms of our
+hands.
+About two or three days before I was set at liberty, as
+I was entertaining the court with this kind of feat, there
+arrived an express to inform his majesty, that some of his
+subjects, riding near the place where I was first taken up,
+had seen a great black substance lying on the ground, [...]
+they would undertake to bring it with only five horses.
+FANNY BURNEY, 1778
+You can’t think how oddly my head feels; full of powder
+and black pins, and a great cushion on the top of it.
+if you’ll say that, you’ll say anything: however, if you
+swear till you’re black in the face, I sha’n’t believe you;
+for nobody sha’n’t persuade me out of my senses, that I’m
+resolved.
+Ridiculous, I told him, was a term which he would find
+no one else do him the favour to make use of, in speaking of
+the horrible actions belonging to the old story he made so
+light of; ’actions’ continued I, ’which would dye still deeper
+the black annals of Nero or Caligula.
+
+JANE AUSTEN, 1813
+The ladies were somewhat more fortunate, for they had
+the advantage of ascertaining from an upper window, that
+he wore a blue coat and rode a black horse.
+CHARLOTTE BRONTE, 1847
+And then she had such a fine head of hair; raven black
+and so becomingly arranged: a crown of thick plaits behind,
+and in front the longest, the glossiest curls I ever saw.
+Afternoon arrived: Mrs. Fairfax assumed her best black
+satin gown, her gloves, and her gold watch; for it was her
+part to receive the company,- to conduct the ladies to their
+rooms, Adele, too, would be dressed: though I thought she
+had little chance of being introduced to the party that day at
+least.
+Fluttering veils and waving plumes filled the vehicles; two
+of the cavaliers were young, dashing looking gentlemen; the
+third was Mr. Rochester, on his black horse, Mesrour, Pilot
+bounding before him; at his side rode a lady, and he and she
+were the first of the party.
+The noble bust, the sloping shoulders, the graceful neck,
+the dark eyes and black ringlets were all there; - but her
+face?
+Mrs. Fairfax was summoned to give information respect-
+ing the resources of the house in shawls, dresses, draperies
+of any kind; and certain wardrobes of the third storey were
+ransacked, and their contents, in the shape of brocaded
+and hooped petticoats, satin sacques, black modes, lace
+lappets, etc, were brought down in armfuls by the abi-
+gails; then a selection was made, and such things as were
+chosen were carried to the boudoir within the drawing room.
+NATHANIEL HAWTHORNE, 1850
+Doubtless, however, either of these stern and black
+browed Puritans would have thought it quite a sufficient ret-
+ribution for his sins that, after so long a lapse of years, the
+old trunk of the family tree, with so much venerable moss
+upon it, should have borne, as its topmost bough, an idler
+like myself.
+The Custom House marker imprinted it, with a stencil and
+black paint, on pepper bags, and baskets of anatto, and cigar
+boxes, and bales of all kinds of dutiable merchandise, in
+testimony that these commodities had paid the impost, and
+gone regularly through the office.
+Before this ugly edifice, and between it and the wheel
+track of the street, was a grass plot, much overgrown
+with burdock, pig weed, apple pern, and such unsightly
+vegetation, which evidently found something congenial in
+the soil that had so early borne the black flower of civilised
+society, a prison.
+CHARLES DICKENS, 1861
+I still held her forcibly down with all my strength, like a
+prisoner who might escape; and I doubt if I even knew who
+she was, or why we had struggled, or that she had been in
+flames, or that the flames were out, until I saw the patches of
+tinder that had been her garments no longer alight but falling
+in a black shower around us.
+The sudden exclusion of the night, and the substitution of
+black darkness in its place, warned me that the man had
+closed a shutter.
+He had a boat cloak with him, and a black canvas bag;
+and he looked as like a river pilot as my heart could have
+wished.
+The marshes were just a long black horizontal line then,
+as I stopped to look after him; and the river was just another
+horizontal line, not nearly so broad nor yet so black; and the
+sky was just a row of long angry red lines and dense black
+lines intermixed.
+G.K. CHESTERTON, 1908
+The tall hat and long frock coat were black; the face, in
+an abrupt shadow, was almost as dark.
+He wore an old fashioned black chimney pot hat; he
+was wrapped in a yet more old fashioned cloak, black and
+ragged; and the combination gave him the look of the early
+villains in Dickens and Bulwer Lytton.
+A long, lean, black cigar, bought in Soho for twopence,
+stood out from between his tightened teeth, and altogether he
+looked a very satisfactory specimen of the anarchists upon
+whom he had vowed a holy war.
+He had a black French beard cut square and a black
+English frock coat cut even squarer.
+SOMERSET W. MAUGHAM, 1915
+She wore a black dress, and her only ornament was a gold
+chain, from which hung a cross.
+It was a large black stove that stood in the hall and was
+only lighted if the weather was very bad and the Vicar had a
+cold.
+And the poor lady, so small in her black satin, shrivelled
+up and sallow, with her funny corkscrew curls, took the little
+boy on her lap and put her arms around him and wept as
+though her heart would break.
+D.4
+Yellow
+DANIEL DEFOE, 1719
+The colour of his skin was not quite black, but very tawny;
+and yet not an ugly, yellow, nauseous tawny, as the Brazil-
+ians and Virginians, and other natives of America are, but of
+a bright kind of a dun olive colour, that had in it something
+very agreeable, though not very easy to describe.
+JONATHAN SWIFT, 1726
+The projector of this cell was the most ancient student of
+the academy; his face and beard were of a pale yellow; his
+hands and clothes daubed over with filth.
+The hair of both sexes was of several colours, brown, red,
+black, and yellow.
+I forgot another circumstance (and perhaps I might
+have the reader’s pardon if it were wholly omitted), that
+while I held the odious vermin in my hands, it voided its
+filthy excrements of a yellow liquid substance all over my
+clothes; but by good fortune there was a small brook hard
+by, where I washed myself as clean as I could; although
+I durst not come into my master’s presence until I were
+sufficiently aired.
+
+WILLIAM MAKEPEACE THACKERAY, 1848
+Joseph still continued a huge clattering at the poker and
+tongs, puffing and blowing the while, and turning as red as
+his yellow face would allow him.
+Why, he had the yellow fever three times; twice at Nas-
+sau, and once at St.
+At one end of the hall is the great staircase all in black oak,
+as dismal as may be, and on either side are tall doors with
+stags’ heads over them, leading to the billiard room and the
+library, and the great yellow saloon and the morning rooms.
+He’s never content unless he gets my yellow sealed wine,
+which costs me ten shillings a bottle, hang him!
+JAMES JOYCE, 1914
+I liked the last best because its leaves were yellow.
+Breakfast was over in the boarding house and the table
+of the breakfast room was covered with plates on which lay
+yellow streaks of eggs with morsels of bacon fat and bacon
+rind.
+An immense scarf of peacock blue muslin was wound
+round her hat and knotted in a great bow under her chin;
+and she wore bright yellow gloves, reaching to the elbow.
+His face, shining with raindrops, had the appearance of
+damp yellow cheese save where two rosy spots indicated
+the cheekbones.
+While the point was being debated a tall agile gentleman
+of fair complexion, wearing a long yellow ulster, came from
+the far end of the bar.
+I saw that he had great gaps in his mouth between his
+yellow teeth.
+On the closed square piano a pudding in a huge yellow
+dish lay in waiting and behind it were three squads of bot-
+tles of stout and ale and minerals, drawn up according to
+the colours of their uniforms, the first two black, with brown
+and red labels, the third and smallest squad white, with trans-
+verse green sashes.
+A dull yellow light brooded over the houses and the river;
+and the sky seemed to be descending.
+F. SCOTT FITZGERALD, 1920
+The Gothic halls and cloisters were infinitely more myste-
+rious as they loomed suddenly out of the darkness, outlined
+each by myriad faint squares of yellow light.
+His face was cast in the same yellow wax as in the cafe,
+neither the dull, pasty color of a dead man—rather a sort of
+virile pallor—nor unhealthy, you’d have called it; but like a
+strong man who’d worked in a mine or done night shifts in a
+damp climate.
+The two hours’ ride were like days, and he nearly cried
+aloud with joy when the towers of Princeton loomed up be-
+side him and the yellow squares of light filtered through the
+blue rain.
+Browsing in her library, Amory found a tattered gray book
+out of which fell a yellow sheet that he impudently opened.
+There was that shade of glorious yellow hair, the desire
+to imitate which supports the dye industry.
+F. SCOTT FITZGERALD, 1922
+That this feeble, unintelligent old man was possessed of
+such power that, yellow journals to the contrary, the men in
+the republic whose souls he could not have bought directly
+or indirectly would scarcely have populated White Plains,
+seemed as impossible to believe as that he had once been a
+pink and white baby.
+He bulges in other places his paunch bulges, propheti-
+cally, his words have an air of bulging from his mouth, even
+his dinner coat pockets bulge, as though from contamination,
+with a dog eared collection of time tables, programmes, and
+miscellaneous scraps on these he takes his notes with great
+screwings up of his unmatched yellow eyes and motions of
+silence with his disengaged left hand.
+It was a crackling dusk when they turned in under the
+white fac¸ade of the Plaza and tasted slowly the foam and
+yellow thickness of an egg nog.
+He had fixed his aunt with the bright yellow eye, giving
+her that acute and exaggerated attention that young males
+are accustomed to render to all females who are of no further
+value.
+On the appointed Wednesday in February Anthony had
+gone to the imposing offices of Wilson, Hiemer and Hardy
+and listened to many vague instructions delivered by an en-
+ergetic young man of about his own age, named Kahler, who
+wore a defiant yellow pompadour, and in announcing him-
+self as an assistant secretary gave the impression that it was
+a tribute to exceptional ability.
+Joe Hull had a yellow beard continually fighting through
+his skin and a low voice which varied between basso pro-
+fundo and a husky whisper.
+
diff --git a/CNE1T4oBgHgl3EQf9wYh/content/tmp_files/load_file.txt b/CNE1T4oBgHgl3EQf9wYh/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..efc737e708cd6a9de5f5d72bc2ad83d79dda227e
--- /dev/null
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@@ -0,0 +1,915 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf,len=914
+page_content='Color Me Intrigued: Quantifying Usage of Colors in Fiction  Siyan Li  Stanford University  siyanli@stanford.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='edu  Abstract  We present preliminary results in quantitative analyses of  color usage in selected authors’ works from LitBank.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Using  Glasgow Norms, human ratings on 5000+ words, we measure  attributes of nouns dependent on color terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Early results  demonstrate a significant increase in noun concreteness over  time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We also propose future research directions for compu-  tational literary color analytics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 1  1  Introduction  All great writers are great colourists, Virginia Woolf once  stated (Woolf 1934).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Analyzing colors in literary work  across time and authors has fascinated the field of literature,  philosophy, and psychology (Skard 1946).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Most literary analyses of colors focus on only one author,  one work, or one historical era.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' There has been very few  large-scale analyses of color usage shifts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Recently, natural  language processing (NLP) has progressed in fields poten-  tially relevant to literary color analyses, such as dependency  parsing (Qi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2020) and named entity recognition (Li  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Leveraging these tools expedites localization of  spans of interest, increasing efficiency and ease of larger-  scale literary analyses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  What makes literary color analyses interesting for nat-  ural language processing?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Authors utilize colors in nu-  merous ways, and NLP tools should capture this variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  While Goethe uses colors as a backdrop of his narratives,  only using them to emphasize the plastic shapes of objects  (Bruns 1928), Dante’s coloring in his Divine Comedy dis-  plays more symbolic undertones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The colors on the three  faces of Dante’s Lucifer can be related to the three horses  of the Apocalypse (Skard 1946).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The sudden absence of  green in Heavenly Paradise may stem from green’s associ-  ation with hope, and Dante’s Paradise eliminates the need  for hope since it fulfills all wishes (Austin 1933).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' In con-  trast, James Joyce’s green can be interpreted to symbolize  absinthe (Earle 2003) and the author’s frustration with the  Irish Catholic Church (Xie 2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' For more contemporary  Copyright © 2023, Association for the Advancement of Artificial  Intelligence (www.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='aaai.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='org).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' All rights reserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  1All code and data used are available at https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='com/  siyan-sylvia-li/ColorLit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  writers, Virginia Woolf’s blue in To the Lighthouse accom-  panies Mrs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Ramsay for her Madonna role and her mix-  ture of radiance and somberness (Stewart 1985).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The same  blue manifests cholera and illness in Edgar Allan Poe’s The  Masque of the Red Death (Yoon 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Despite some sub-  jectivity in these interpretations, the existence of differences  in color usages are absolute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We want to examine whether  current NLP tools “understand” these differences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  We propose a novel line of research using word embed-  dings and pre-trained language models to quantify color us-  ages in literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Specifically, we measure the attributes of  nouns dependent on color adjectives according to the Glas-  gow Norms (Scott et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Preliminary results demon-  strate statistically significant trends over time for certain col-  ors’ Glasgow Norm attributes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We present future research  directions and plausible experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Our proposed framework can supplement literary color  analyses research and provide additional insight for color  usages comparisons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Looking at literature and creativity  through the lens of colors is informative because of the  prevalence of color terms in literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Color terms can serve  as anchoring points of comparison between authors, and po-  tentially between humans and language models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  2  Related Work  The most similar work to ours would be Rabinovich and  Carmeli (2022), a study of color term usage by both non-  color-blind and color-blind individuals on Reddit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The au-  thors discover significant differences in certain color terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  They then concentrate on the nouns that are modified by  color words, using dependency parsing to obtain NOUN  words in an AMOD dependency pair with an ADJ color  term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The authors identify significant discrepancies between  the two populations in imageability (Scott et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2019) values  of color-modified nouns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Our preliminary work is method-  ologically similar, but we study literature instead.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Addition-  ally, our work more extensively leverages labels from the  Glasgow Norms by using three dimensions instead of one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Word embeddings play a crucial role in computational  social science.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Garg et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' (2018) leverages Word2vec  (Mikolov et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2013) to reflect changes in relationships be-  tween the embedding representing women and different ad-  jectives as potentially a result of the feminist movement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' A  similar work, Bailey, Williams, and Cimpian (2022), show-  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='03559v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='CL]  9 Jan 2023  cases that people = man by comparing distances be-  tween word embeddings of trait words of people, men, and  women respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We are interested in similar techniques  in a literary color analysis context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  3  Dataset  We use LitBank (Bamman, Popat, and Shen 2019), a Euro-  centric collection of 100 English fictions from 75 authors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  We conduct a scrape of Project Gutenberg using LitBank’s  Gutenberg ID’s to obtain the full text of each work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The gen-  res consist primarily of realistic novels, with few exceptions  of science fiction (H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Wells, Mary Shelley), fantasy (Bram  Stoker, Oscar Wilde), and horror (Edgar Allan Poe).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  4  Methodology  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='1  Extracting Modified Nouns  Colors and Synonyms  We select common colors and cu-  rate a list of their synonyms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The colors include “red”,  “green”, “black”, “white”, “blue”, “brown”, “gray”, “yel-  low”, “pink”, and “purple”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' All color terms and their syn-  onyms are in Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Each set of sentences from a  Project Gutenberg E-book are split into lemmatized words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  We choose sentences containing either our specified color  adjectives or their synonyms for dependency parsing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Dependency Parsing  Although Rabinovich and Carmeli  (2022) strictly studies nouns modified by color terms  through the AMOD dependency, this would be limiting in  lyrical writing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' For instance, “she has eyes of sapphire” de-  scribes blue eyes and should be included in our analysis, but  dependency parsing would categorize “eyes” and “saphire”  to linked by NMOD instead of AMOD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Therefore, we ex-  pand upon our pool of nouns by including all nouns with  a dependency link to our color terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We employ Stanza’s  Dependency Parser (Qi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Upon obtaining depen-  dencies on a sentence, we perform a filtering process to re-  tain the relevant head-dependent pairs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The specific filter-  ing process is as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' For each head-dependent pair:  (1) Lemmatize both the head and the dependent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' (2) Iter-  ate through all color words and their synonyms;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' if none of  them is present in either the head or the dependent, prune  out this pair.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' (3) If the other word in the dependency pair is  not a noun or a proper noun, prune out this pair.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='2  Glasgow Norm Models  The Glasgow Norms are a list of 5,553 words with corre-  sponding normative human ratings on different psycholin-  guistic dimensions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Our ongoing work concentrates on: (1)  Imageability (IMAG), the ease of summoning a mental im-  age from a word;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' (2) Concreteness (CNC), the extent to  which words can be experienced to our senses;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and (3) Va-  lence (VAL), how positive or negative a word’s value is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We  hypothesize that different authors differ on the imageabili-  ty/concreteness/valence values of color-dependent nouns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Although the Glasgow Norms vocabulary is extensive,  we still hope to handle unseen words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' FastText embeddings  (Joulin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2016) reduced to 100 dimensions are used to  train separate 1-layer Multi-Layer Perceptron (MLP) models  Color  # of Occurrences  Color  # of Occurrences  red  2888  green  1839  black  3325  white  4990  blue  1622  brown  1206  gray  1575  yellow  848  pink  648  purple  545  Table 1: The total numbers of occurrences of our selected  color terms in the 100 LitBank novels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' These are instances  where the color terms act as either a dependent or a depen-  dency head.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  to predict these values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We choose FastText for its adaptabil-  ity for unseen words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Prior to training, all scores are normal-  ized to the 0 to 1 range for better interpretability, consistent  with Rabinovich and Carmeli (2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Three neural networks  with sigmoid activations are trained on these data, and eval-  uated on a held-out test set with an 8:1:1 split.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We use Pear-  son’s correlation between predictions and ground truths as  our metric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Rabinovich and Carmeli (2022) reports a Pear-  son’s correlation of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='76 for their IMAG model on a random  held-out set, while ours achieves 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='79 on the test set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We un-  derstand that the held-out test set may be different, but this  indicates that our IMAG model should as potent as the prior  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Our CNC model and VAL model achieve correlation  scores of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='83 and 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='76, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  To prevent repeated occurrences of a word affecting the  average Glasgow Norm values, the dependent nouns are  deduplicated when computing the averages.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  5  Preliminary Results  Despite our analyses on LitBank yield statistically signifi-  cant results when analyzed across time, this could stem from  an imbalance in the distribution of publication time in Lit-  Bank.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' This paper aims to establish a preliminary framework  for studying color usages in literature, and current results  would need corroboration from additional texts from differ-  ent eras and genres.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='1  Color-dependent Nouns  We conduct both quantitative and qualitative analyses on  color-dependent nouns in LitBank through both comput-  ing average Glasgow Norm values and through inspection  of most frequently associated nouns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Additional analyses of  color term frequencies are in Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Out of all unique nouns, 1299 are within the Glas-  gow Norm vocabulary, and 1924 are OOV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We use our  trained MLPs to infer Glasgow Norm scales of the out-  of-vocabulary nouns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' After recognizing an upward trend in  IMAG and CNC, we compute Pearson’s correlations be-  tween publication year and average IMAG and CNC val-  ues for all color terms in novels where the color is present  (Table 2, Figure 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The IMG and CNC values increase sig-  nificantly over time for black, white, yellow, and pink.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' This  indicates that the nouns associated with these color terms  Figure 1: Imageability plots for the color terms with signif-  icant results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We omit the concreteness plots here because  IMAG and CNC are highly correlated, but we provide the  full set of plots in Appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  become increasingly concrete easier to conjure mental im-  ages of.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' This is consistent with some conclusions from Skard  (1946) that early color usages are obscure and abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Nouns in Individual Works  We observe interesting data  points in our plots (the full sets of figures are available in  Appendix C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' For instance, we notice a significantly lower  valence for red in Edgar Allan Poe’s The Masque of the  Red Death, because the only nouns associated with red are  “death”, “stain”, and “horror”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Similarly, an abnormally low  green valence arises in Henry Fielding’s History of Tom  Jones, a Foundling, because green is attached to “slut”,  “witch”, and “monster”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Nouns over Publication Time  We divide our fictions into  pre-1800’s, 1800 - 1900, and post-1900 based on patterns  in our data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We then deduplicate dependent nouns in each  work so that we can measure most frequent nouns in each  era without thematic motifs biasing our analyses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' A list of  selected color terms and their most dependent nouns in each  of the eras are in Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  From the table we observe a significant shift in frequently  used nouns across time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Pre-1800 dependent nouns are more  abstract and complex compared to post-1800 nouns depen-  dent on the same colors, while there is no significant differ-  ence between 1800 - 1900 and post-1900.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' This is a possible  explanation for the increase in imageability and concrete-  ness over time among LitBank works.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='2  Inter-Author Differences  We plot the Word2vec embeddings of nouns dependent on  the same colors from different authors to decipher how  the color terms are used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Out-of-vocabulary nouns are dis-  carded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' This serves as a crude visualization of different top-  ics associated with these color terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' For instance, when  comparing nouns modified by yellow in works of Fitzger-  ald and Joyce in LitBank, the topic of facial hair (hair, beard,  IMAG Results  Color  Pearson’s r  Color  Pearson’s r  red  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='095*  green  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='059  black  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='257**  white  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='303***  pink  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='534***  yellow  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='340**  CNC Results  Color  Pearson’s r  Color  Pearson’s r  black  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='237**  white  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='239**  pink  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='517***  yellow  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='318***  VAL Results  Color  Pearson’s r  Color  Pearson’s r  green  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='273***  purple  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='210*  Table 2: Pearson’s correlations between published years and  Glasgow Norm values of the 100 fictions for color terms  with sig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' *** p < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='001, ** p < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='05, and * p < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Full results are in Appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Color  Era  Frequent Nouns  pink  Pre-1800  shame,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' guilt,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' folly,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  ribbon,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' indignation  1800 - 1900  cheek,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' face,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' ribbon,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' rose,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' lip  Post-1900  cheek,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' face,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' rose,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' paper,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' bud  black  Pre-1800  color,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' eye,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' grain,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' wave  1800 - 1900  hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' eye,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' shadow,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' dress,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' face  Post-1900  hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' eye,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' dress,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' figure,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' man  white  Pre-1800  face,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' cheek,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' countenance,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  cliff,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' cave  1800 - 1900  face,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' cheek,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' hand,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' man  Post-1900  face,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' hand,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' eye,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' man  yellow  Pre-1800  appearance,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' complexion,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  blossom,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' lustre,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' mist  1800 - 1900  hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' light,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' face,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' glove,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' skin  Post-1900  hair,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' light,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' eye,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' flower,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' house  Table 3: Most frequently color-modified nouns from each  era for selected color terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Example sentences are in Ap-  pendix D  pompadour) only manifests in Fitzgerald’s, while food items  (soup, cheese) appear in Joyce’s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Additional examples are in  Appendix D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  6  Proposal of Future Work  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='1  Further Analyses  Fine-grained Timeline Analyses  Similar to Garg et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  (2018), we can train separate Word2vec models on each  decade of literature in our collection for fine-grained anal-  yses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Preliminary results indicate that certain colors become  black  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='9  IMAG  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='7  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='6  1750  1800  1850  1900  Yearwhite  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='9  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='8  IMAG  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='7  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='6  1750  1800  1850  1900  Yearyellow  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='8  IMAG  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='4  1750  1800  1850  1900  Yearpink  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='8  IMAG  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='2  1750  1800  1850  1900  YearFigure 2: Word2vec embeddings of nouns modified by yel-  low in novels by F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Scott Fitzgerald (red points) and James  Joyce (blue points).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  increasingly associated with concrete descriptions (pink as-  sociated with cheeks and face).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We can compute cosine sim-  ilarities between Word2vec embeddings of certain colors  with words such as “face” and “lips”;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' this should increase  over time as we observe increasing presence of colors in  character descriptions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' A similar metric can further quantize  inter-author differences as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Additional Clustering  We demonstrate the prowess of  Word2vec for visualizing color-related topics in this pro-  posal, but word embeddings fail to account for contexts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Further clustering analyses can include embeddings from  context-dependent pre-trained language models such as Sen-  tenceBERT (Reimers and Gurevych 2019) and BERT (De-  vlin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2018).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='2  RQs: From a Literature Perspective  How do colors differ across genres?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  We chose LitBank  for its ease of access and thorough documentations, but one  emerging issue is that LitBank skews heavily towards re-  alistic fictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Due to this imbalance, we cannot compare  color usages meaningfully across genres.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We will include  more books in future analyses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' If we observe significant dif-  ferences in frequencies of different color words or in the  concepts and objects associated with the colors, we can con-  clude that there exists cross-genre differences in color usage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  We already observe such differences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Bram Stoker’s  Dracula (Stoker 1897), a pioneering work in vampire liter-  ature, features numerous descriptions of pale maidens with  their red lips, as well as of scarlet blood and crimson eyes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Therefore, we notice much more frequent usage of the color  red in this work, compared to H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Wells’s The War of the  Worlds (Wells 1897), where red most commonly modifies  weeds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We want to inspect whether the same general pattern  would persist on larger-scale analyses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  How do colors differ across literary forms?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Literary  color analyses often separate novelists and poets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Compar-  isons are often drawn only between two poets or two nov-  elists, but rarely both.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Our hypothesis is that colors usage  in poetry differs significantly from color usage in prose and  novels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Such differences can manifest as a discrepancy in  concreteness (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' in poetry, colors can more often associate  with a concept instead of a concrete object).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Expanding our  research to include poets, preferably those contemporary to  our novelists, should enable us to address this systematically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='3  RQs: From a Social Science Perspective  How do colors differ across cultures and classes?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Dif-  ferent cultures can have different associations with the same  color;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' for instance, white is often a symbol of purity and a  staple at Western weddings, whereas the same color is used  more traditionally in Chinese funerals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' These associations  may reflect socio-economic classes as well (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' white-collar  and blue-collar jobs) through colors frequently co-occurring  with characters from different cultures and societal classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  To analyze this, we will utilize named entity recognition to  link colors to characters, operating with more context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Pur-  suing this research direction would involve translated work,  instead of using only Euro-centric collections of literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The social class of a character can either be looked up on-  line or inferred by a model to automate the process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We can  then cluster character colors by cultures and classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  How do colors affect biases and stereotypes?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Current-  day color associations, such as pink with girls and blue with  boys, can fuel biases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' For instance, boys who enjoy wearing  pink may be regarded as “girly” and overly feminine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Cer-  tain colors also contain associations with LGBTQ+ commu-  nities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We are interested in identifying how these color-based  biases (going beyond race) manifest in literature and online  communities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We can study this by finding colors associated  with characters of a demographic group of interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Tracing  through past literature may also shed light upon the evolu-  tion of color associations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  7  Discussion  Our work serves as a step towards more systematic analy-  ses of color usages in literature using natural language pro-  cessing tools.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Following prior work, we propose using The  Glasgow Norms and word embeddings as tools for quan-  tifying color usage differences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We demonstrate significant  increasing trends in imageability and concreteness in color-  dependent nouns over time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  One limitation is the range of language we are capable of  handling is constrained by the language models we employ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Our current collection does not have many pre-1800 pieces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  While it is possible to increase the representation of pre-  1800s literature, the domain shift in English style and word  conventions may require different word embedding and pre-  trained models to embed narratives (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Chaucer often uses  “red” in place of “read”, standard of his time, but causes am-  biguity when processing texts on a large scale).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Given such  shifts in vocabulary and sentence structures, we may fail to  provide meaningful insights into earlier literature, since the  word embeddings may have disjoint vocabularies, and mod-  els such as SentenceBERT are trained on more modern texts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  yellow  bhaird  pompadour  4  2  wax  0  sheet  square  tiewh  streak  journal  knee  gingry  boot  sol  dadchild  2  dwaistebtnd  cap  itaivgri  reflestiartle  4  sobbing  twilight  Jight  sun  gw  jnsoence  paese  Mkeen  melon  6  flower  2  3  5  6  7  8  9  4References  Austin, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 1933.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Heavenly Gold;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' A Study of the Use of  Color in Dante.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Philological Quarterly, 12: 44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Bailey, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Williams, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and Cimpian, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Based  on billions of words on the internet, people= men.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Science  Advances, 8(13): eabm2463.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Bamman, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Popat, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and Shen, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' An annotated  dataset of literary entities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
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+page_content=' F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 1985.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
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+page_content=' Twentieth  Century Literature, 31(4): 438–458.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Publisher: [Duke Uni-  versity Press, Hofstra University].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Stoker, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 1897.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Dracula: 1897.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
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+page_content=' amethyst  Table 4: List of color words used and their synonyms  Woolf,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 1934.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Walter Sickert: A Conversation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and  Virginia Woolf at the Hogarth Press.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Xie, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2015.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Color as Metaphor-A Study of Joyce’s Use of”  Black” and” Green” in Dubliners and A Portrait of the Artist  as a Young Man.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' English Language and Literature Studies,  5(4): 61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Yoon, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Color Symbolisms of Diseases: Edgar Al-  lan Poe’s “The Masque of the Red Death”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' The Explicator,  79(1-2): 21–24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  A  Color terms and their synonyms used  We list the color terms used in this work, along with their  corresponding synonyms obtained through manual inspec-  tion on Thesaurus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='com entries, in Table 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  B  Normalized Frequencies Over Time  After filtering through sentences in LitBank for relevant de-  pendence pairs, the absolute frequencies of each color term  are listed in Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We also calculate the normalized fre-  quencies (absolute frequency divided by the total number of  words) for the 100 fictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' We notice an increasing trend in  the normalized frequencies over time for LitBank, and com-  pute Pearson’s correlations between normalized frequencies  of color terms and time to verify this trend (Table 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  We present the scatter plots of normalized frequencies in  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  C  Glasgow Norm Plots of Modified Nouns  Over Time  The plots corresponding to how color-modified nouns  change over time with respect to their Glasgow Norm  Color  Pearson’s r  Color  Pearson’s r  red  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
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+page_content='059  white  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='161  blue  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='104  brown  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='148  gray  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='072  yellow  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='01  pink  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='081  purple  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='210*  Table 6: Full list of Pearson’s correlations between published  years and Glasgow Norm values of the 100 fictions for each  color term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' *** p < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='001, ** p < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='05, and * p < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  D  Example of Color Term Usages  In the following usage examples, the color terms are un-  derlined, bolded and colored, while the dependent noun is  bolded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='1  Pink  HENRY FIELDING, 1749  Adorned with all the charms in which nature can array  her;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' bedecked with beauty, youth, sprightliness, innocence,  modesty, and tenderness, breathing sweetness from her rosy  lips, and darting brightness from her sparkling eyes, the  lovely Sophia comes!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  FANNY BURNEY, 1778  We were sitting in this manner, he conversing with all  gaiety, I looking down with all foolishness, when that fop  who had first asked me to dance, [.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='] I interrupted him I  blush for my folly, with laughing;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' yet I could not help it;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  for, added to the man’s stately foppishness, [.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='] that I could  not for my life preserve my gravity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  ANN WARD RADCLIFFE, 1794  As they descended, they saw at a distance, on the right,  one of the grand passes of the Pyrenees into Spain, gleaming  with its battlements and towers to the splendour of the set-  ting rays, yellow tops of woods colouring the steeps below,  while far above aspired the snowy points of the mountains,  still reflecting a rosy hue.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Conscious innocence could not prevent a blush from  stealing over Emily’s cheek;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' she trembled, and looked con-  fusedly under the bold eye of Madame Cheron, who blushed  also;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' but hers was the blush of triumph, such as sometimes  stains the countenance of a person, congratulating himself  on the penetration which had taught him to suspect another,  and who loses both pity for the supposed criminal, and  indignation of his guilt, in the gratification of his own vanity  CHARLOTTE BRONTE, 1847  Her beauty, her pink cheeks and golden curls, seemed to  give delight to all who looked at her, and to purchase indem-  nity for every fault.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Its garden, too, glowed with flowers: hollyhocks had  sprung up tall as trees, lilies had opened, tulips and roses  were in bloom;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' the borders of the little beds were gay with  pink thrift and crimson double daisies;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' the sweetbriars gave  out, morning and evening, their scent of spice and apples;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  and these fragrant treasures were all useless for most of the  inmates of Lowood, except to furnish now and then a hand-  ful of herbs and blossoms to put in a coffin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  She pulled out of her box, about ten minutes ago, a  little pink silk frock;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' rapture lit her face as she unfolded  it;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' coquetry runs in her blood, blends with her brains, and  seasons the marrow of her bones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  ARTHUR CONAN DOYLE, 1892  That trick of staining the fishes’ scales of a delicate pink  is quite peculiar to China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Her violet eyes shining, her lips parted, a pink flush upon  her cheeks, all thought of her natural reserve lost in her over-  powering excitement and concern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  As we approached, the door flew open, and a little blonde  woman stood in the opening, clad in some sort of light  Figure 3: Log-scale scatter plots of normalized color term frequencies for each publication in LitBank.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
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+page_content='4  1750  1800  1850  1900  Yearpurple  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
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+page_content='2  1750  1800  1850  1900  Yearmousseline de soie, with a touch of fluffy pink chiffon at  her neck and wrists.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' WELLS, 1897  It was the fact that all his forehead above his blue glasses  was covered by a white bandage, and that another covered  his ears, leaving not a scrap of his face exposed excepting  only his pink, peaked nose.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' WODEHOUSE, 1919  Jimmy turned into that drug store at the top of the Hay-  market at which so many Londoners have found healing and  comfort on the morning after, and bought the pink drink for  which his system had been craving since he rose from bed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The clerk had finished writing the ticket, and was pressing  labels and a pink paper on him.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' SCOTT FITZGERALD, 1920:  Myra sprang up, her cheeks pink with bruised vanity, the  great bow on the back of her head trembling sympathetically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='2  White  FANNY BURNEY, 1778  She told her niece, that she had been indulging in fanciful  sorrows, and begged she would have more regard for deco-  rum, than to let the world see that she could not renounce an  improper attachment;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' at which Emily’s pale cheek became  flushed with crimson, but it was the blush of pride, and she  made no answer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  MARY WOLLSTONECRAFT, 1788  Henry started at the sight of her altered appearance;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' the  day before her complexion had been of the most pallid hue;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  but now her cheeks were flushed, and her eyes enlivened  with a false vivacity, an unusual fire.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  JANE AUSTEN, 1813  Her pale face and impetuous manner made him start, and  before he could recover himself to speak, she, in whose mind  every idea was superseded by Lydia’s situation, hastily ex-  claimed, “I beg your pardon, but I must leave you.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  From his garden, Mr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Collins would have led them round  his two meadows;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' but the ladies, not having shoes to en-  counter the remains of a white frost, turned back  ELIZABETH CLEGHORN GASKELL, 1855  She lay curled up on the sofa in the back drawing room in  Harley Street looking very lovely in her white muslin and  blue ribbons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  She found out that the water in the urn was cold, and or-  dered up the great kitchen tea kettle;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' the only consequence  of which was that when she met it at the door, and tried to  carry it in, it was too heavy for her, and she came in pouting,  with a black mark on her muslin gown, and a little round  white hand indented by the handle, which she took to show  to Captain Lennox, just like a hurt child, and, of course, the  remedy was the same in both cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  But he had the same large, soft eyes as his daughter, eyes  which moved slowly and almost grandly round in their or-  bits, and were well veiled by their transparent white eyelids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  CHARLES DICKENS, 1861  I lighted my fire, which burnt with a raw pale flare at that  time of the morning, and fell into a doze before it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  She’s all in white,’ he says, ‘wi’ white flowers in her hair,  and she’s awful mad, and she’s got a shroud hanging over her  arm, and she says she’ll put it on me at five in the morning.’  When we was put in the dock, I noticed first of all what  a gentleman Compeyson looked, wi’ his curly hair and his  black clothes and his white pocket handkercher, and what  a common sort of a wretch I looked.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  ELIZABETH VON ARNIM, 1898  There are so many bird cherries round me, great trees with  branches sweeping the grass, and they are so wreathed just  now with white blossoms and tenderest green that the gar-  den looks like a wedding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  When that time came, and when, before it was over, the  acacias all blossomed too, and four great clumps of pale, sil-  very pink peonies flowered under the south windows, I felt  so absolutely happy, and blest, and thankful, and grateful,  that I really cannot describe it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='3  Black  JONATHAN SWIFT, 1726  In his right waistcoat pocket we found a prodigious bun-  dle of white thin substances, folded one over another, about  the bigness of three men, tied with a strong cable, and  marked with black figures;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' which we humbly conceive to  be writings, every letter almost half as large as the palm of  our hands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  In the left pocket were two black pillars irregularly  shaped: we could not, without difficulty, reach the top of  them, as we stood at the bottom of his pocket.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  In one of these cells were several globes, or balls, of a  most ponderous metal, about the bigness of our heads, and  requiring a strong hand to lift them: the other cell contained a  heap of certain black grains, but of no great bulk or weight,  for we could hold above fifty of them in the palms of our  hands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  About two or three days before I was set at liberty, as  I was entertaining the court with this kind of feat, there  arrived an express to inform his majesty, that some of his  subjects, riding near the place where I was first taken up,  had seen a great black substance lying on the ground, [.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=']  they would undertake to bring it with only five horses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  FANNY BURNEY, 1778  You can’t think how oddly my head feels;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' full of powder  and black pins, and a great cushion on the top of it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  if you’ll say that, you’ll say anything: however, if you  swear till you’re black in the face, I sha’n’t believe you;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  for nobody sha’n’t persuade me out of my senses, that I’m  resolved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Ridiculous, I told him, was a term which he would find  no one else do him the favour to make use of, in speaking of  the horrible actions belonging to the old story he made so  light of;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' ’actions’ continued I, ’which would dye still deeper  the black annals of Nero or Caligula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  JANE AUSTEN, 1813  The ladies were somewhat more fortunate, for they had  the advantage of ascertaining from an upper window, that  he wore a blue coat and rode a black horse.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  CHARLOTTE BRONTE, 1847  And then she had such a fine head of hair;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' raven black  and so becomingly arranged: a crown of thick plaits behind,  and in front the longest, the glossiest curls I ever saw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Afternoon arrived: Mrs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Fairfax assumed her best black  satin gown, her gloves, and her gold watch;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' for it was her  part to receive the company,- to conduct the ladies to their  rooms, Adele, too, would be dressed: though I thought she  had little chance of being introduced to the party that day at  least.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Fluttering veils and waving plumes filled the vehicles;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' two  of the cavaliers were young, dashing looking gentlemen;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' the  third was Mr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Rochester, on his black horse, Mesrour, Pilot  bounding before him;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' at his side rode a lady, and he and she  were the first of the party.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The noble bust, the sloping shoulders, the graceful neck,  the dark eyes and black ringlets were all there;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' - but her  face?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Mrs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' Fairfax was summoned to give information respect-  ing the resources of the house in shawls, dresses, draperies  of any kind;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and certain wardrobes of the third storey were  ransacked, and their contents, in the shape of brocaded  and hooped petticoats, satin sacques, black modes, lace  lappets, etc, were brought down in armfuls by the abi-  gails;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' then a selection was made, and such things as were  chosen were carried to the boudoir within the drawing room.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  NATHANIEL HAWTHORNE, 1850  Doubtless, however, either of these stern and black  browed Puritans would have thought it quite a sufficient ret-  ribution for his sins that, after so long a lapse of years, the  old trunk of the family tree, with so much venerable moss  upon it, should have borne, as its topmost bough, an idler  like myself.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The Custom House marker imprinted it, with a stencil and  black paint, on pepper bags, and baskets of anatto, and cigar  boxes, and bales of all kinds of dutiable merchandise, in  testimony that these commodities had paid the impost, and  gone regularly through the office.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Before this ugly edifice, and between it and the wheel  track of the street, was a grass plot, much overgrown  with burdock, pig weed, apple pern, and such unsightly  vegetation, which evidently found something congenial in  the soil that had so early borne the black flower of civilised  society, a prison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  CHARLES DICKENS, 1861  I still held her forcibly down with all my strength, like a  prisoner who might escape;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and I doubt if I even knew who  she was, or why we had struggled, or that she had been in  flames, or that the flames were out, until I saw the patches of  tinder that had been her garments no longer alight but falling  in a black shower around us.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The sudden exclusion of the night, and the substitution of  black darkness in its place, warned me that the man had  closed a shutter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  He had a boat cloak with him, and a black canvas bag;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  and he looked as like a river pilot as my heart could have  wished.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The marshes were just a long black horizontal line then,  as I stopped to look after him;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and the river was just another  horizontal line, not nearly so broad nor yet so black;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and the  sky was just a row of long angry red lines and dense black  lines intermixed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' CHESTERTON, 1908  The tall hat and long frock coat were black;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' the face, in  an abrupt shadow, was almost as dark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  He wore an old fashioned black chimney pot hat;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' he  was wrapped in a yet more old fashioned cloak, black and  ragged;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' and the combination gave him the look of the early  villains in Dickens and Bulwer Lytton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  A long, lean, black cigar, bought in Soho for twopence,  stood out from between his tightened teeth, and altogether he  looked a very satisfactory specimen of the anarchists upon  whom he had vowed a holy war.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  He had a black French beard cut square and a black  English frock coat cut even squarer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  SOMERSET W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' MAUGHAM, 1915  She wore a black dress, and her only ornament was a gold  chain, from which hung a cross.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  It was a large black stove that stood in the hall and was  only lighted if the weather was very bad and the Vicar had a  cold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  And the poor lady, so small in her black satin, shrivelled  up and sallow, with her funny corkscrew curls, took the little  boy on her lap and put her arms around him and wept as  though her heart would break.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='4  Yellow  DANIEL DEFOE, 1719  The colour of his skin was not quite black, but very tawny;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  and yet not an ugly, yellow, nauseous tawny, as the Brazil-  ians and Virginians, and other natives of America are, but of  a bright kind of a dun olive colour, that had in it something  very agreeable, though not very easy to describe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  JONATHAN SWIFT, 1726  The projector of this cell was the most ancient student of  the academy;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' his face and beard were of a pale yellow;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' his  hands and clothes daubed over with filth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The hair of both sexes was of several colours, brown, red,  black, and yellow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  I forgot another circumstance (and perhaps I might  have the reader’s pardon if it were wholly omitted), that  while I held the odious vermin in my hands, it voided its  filthy excrements of a yellow liquid substance all over my  clothes;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' but by good fortune there was a small brook hard  by, where I washed myself as clean as I could;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' although  I durst not come into my master’s presence until I were  sufficiently aired.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  WILLIAM MAKEPEACE THACKERAY, 1848  Joseph still continued a huge clattering at the poker and  tongs, puffing and blowing the while, and turning as red as  his yellow face would allow him.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Why, he had the yellow fever three times;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' twice at Nas-  sau, and once at St.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  At one end of the hall is the great staircase all in black oak,  as dismal as may be, and on either side are tall doors with  stags’ heads over them, leading to the billiard room and the  library, and the great yellow saloon and the morning rooms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  He’s never content unless he gets my yellow sealed wine,  which costs me ten shillings a bottle, hang him!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  JAMES JOYCE, 1914  I liked the last best because its leaves were yellow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Breakfast was over in the boarding house and the table  of the breakfast room was covered with plates on which lay  yellow streaks of eggs with morsels of bacon fat and bacon  rind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  An immense scarf of peacock blue muslin was wound  round her hat and knotted in a great bow under her chin;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  and she wore bright yellow gloves, reaching to the elbow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  His face, shining with raindrops, had the appearance of  damp yellow cheese save where two rosy spots indicated  the cheekbones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  While the point was being debated a tall agile gentleman  of fair complexion, wearing a long yellow ulster, came from  the far end of the bar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  I saw that he had great gaps in his mouth between his  yellow teeth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  On the closed square piano a pudding in a huge yellow  dish lay in waiting and behind it were three squads of bot-  tles of stout and ale and minerals, drawn up according to  the colours of their uniforms, the first two black, with brown  and red labels, the third and smallest squad white, with trans-  verse green sashes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  A dull yellow light brooded over the houses and the river;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  and the sky seemed to be descending.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' SCOTT FITZGERALD, 1920  The Gothic halls and cloisters were infinitely more myste-  rious as they loomed suddenly out of the darkness, outlined  each by myriad faint squares of yellow light.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  His face was cast in the same yellow wax as in the cafe,  neither the dull, pasty color of a dead man—rather a sort of  virile pallor—nor unhealthy, you’d have called it;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' but like a  strong man who’d worked in a mine or done night shifts in a  damp climate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  The two hours’ ride were like days, and he nearly cried  aloud with joy when the towers of Princeton loomed up be-  side him and the yellow squares of light filtered through the  blue rain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Browsing in her library, Amory found a tattered gray book  out of which fell a yellow sheet that he impudently opened.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  There was that shade of glorious yellow hair, the desire  to imitate which supports the dye industry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content=' SCOTT FITZGERALD, 1922  That this feeble, unintelligent old man was possessed of  such power that, yellow journals to the contrary, the men in  the republic whose souls he could not have bought directly  or indirectly would scarcely have populated White Plains,  seemed as impossible to believe as that he had once been a  pink and white baby.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  He bulges in other places his paunch bulges, propheti-  cally, his words have an air of bulging from his mouth, even  his dinner coat pockets bulge, as though from contamination,  with a dog eared collection of time tables, programmes, and  miscellaneous scraps on these he takes his notes with great  screwings up of his unmatched yellow eyes and motions of  silence with his disengaged left hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  It was a crackling dusk when they turned in under the  white fac¸ade of the Plaza and tasted slowly the foam and  yellow thickness of an egg nog.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  He had fixed his aunt with the bright yellow eye, giving  her that acute and exaggerated attention that young males  are accustomed to render to all females who are of no further  value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  On the appointed Wednesday in February Anthony had  gone to the imposing offices of Wilson, Hiemer and Hardy  and listened to many vague instructions delivered by an en-  ergetic young man of about his own age, named Kahler, who  wore a defiant yellow pompadour, and in announcing him-  self as an assistant secretary gave the impression that it was  a tribute to exceptional ability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
+page_content='  Joe Hull had a yellow beard continually fighting through  his skin and a low voice which varied between basso pro-  fundo and a husky whisper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE1T4oBgHgl3EQf9wYh/content/2301.03559v1.pdf'}
diff --git a/CNE5T4oBgHgl3EQfTg-d/content/tmp_files/2301.05537v1.pdf.txt b/CNE5T4oBgHgl3EQfTg-d/content/tmp_files/2301.05537v1.pdf.txt
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@@ -0,0 +1,2268 @@
+Almost Surely
+√
+T Regret Bound for Adaptive LQR
+Yiwen Lu and Yilin Mo
+Abstract—The Linear-Quadratic Regulation (LQR) problem
+with unknown system parameters has been widely studied, but it
+has remained unclear whether ˜O(
+√
+T) regret, which is the best
+known dependence on time, can be achieved almost surely. In
+this paper, we propose an adaptive LQR controller with almost
+surely
+˜O(
+√
+T) regret upper bound. The controller features a
+circuit-breaking mechanism, which circumvents potential safety
+breach and guarantees the convergence of the system parameter
+estimate, but is shown to be triggered only finitely often and
+hence has negligible effect on the asymptotic performance of
+the controller. The proposed controller is also validated via
+simulation on Tennessee Eastman Process (TEP), a commonly
+used industrial process example.
+I. INTRODUCTION
+Adaptive control, the study of decision-making under the
+parametric uncertainty of dynamical systems, has been pur-
+sued for decades [1]–[4]. Although early research mainly
+focused on the the aspect of convergence and stability, recent
+years have witnessed significant advances in the quantitative
+performance analysis of adaptive controllers, especially for
+multivariate systems. In particular, in the adaptive Linear-
+Quadratic Regulation (LQR) setting considered in this paper,
+the controller attempts to solve the stochastic LQR problem
+without access to the true system parameters, and its perfor-
+mance is evaluated via regret, the cumulative deviation from
+the optimal cost over time. This adaptive LQR setting has
+been widely studied in the past decade [5]–[11], but it has
+remained unclear whether adaptive controllers for LQR can
+achieve ˜O(
+√
+T) regret, whose asymptotic dependence on the
+time T is the best known (up to poly-logarithmic factors) 1,
+almost surely.
+Existing regret upper bounds on adaptive LQR, summarized
+in Table I, are either weaker than almost-sure in terms of
+the type of probabilistic guarantee, or suboptimal in terms of
+asymptotic dependence on time. By means of optimism-in-
+face-of-uncertainty [7], Thompson sampling [6], or ϵ-greedy
+algorithm [9], an ˜O(
+√
+T) regret can be achieved with proba-
+bility at least 1 − δ. In other words, these algorithms may not
+converge to the optimal one or could even be destablizing
+with a non-zero probability δ. In practice, such a failure
+probability may hinder the application of these algorithms in
+safety-critical scenarios. From a theoretical perspective, we
+argue that it is highly difficult to extend these algorithms
+to provide stronger performance guarantees. To be specific,
+The
+authors
+are
+with
+the
+Department
+of
+Automa-
+tion
+and
+BNRist,
+Tsinghua
+University,
+Beijing,
+P.R.China.
+Emails:
+luyw20@mails.tsinghua.edu.cn,
+ylmo@tsinghua.edu.cn.
+1It is known that
+√
+T is the optimal L1 rate of regret [9], and we suspect
+that it is also the optimal almost sure rate.
+despite different exploration strategies, the aforementioned
+methods all compute the control input using a linear feedback
+gain synthesized from a least-squares estimate of system
+parameters. Due to Gaussian process noise, the derived linear
+feedback gain may be destabilizing, regardless of the amount
+of data collected. For these algorithms, the probability of such
+catastrophic event is bounded by a positive δ > 0, which is a
+predetermined design parameter and cannot be changed during
+online operation.
+Alternative methods that may preclude the above de-
+scribed failure probability include introducing additional sta-
+bility assumptions, using parameter estimation algorithms with
+stronger convergence guarantees, and adding a layer of safe-
+guard around the linear feedback gain. Faradonbeh et al. [10]
+achieves ˜O(
+√
+T) regret almost surely under the assumption
+that the closed-loop system remains stable all the time, based
+on a stabilization set obtained from adaptive stabilization [12].
+Since the stabilization set is estimated from finite data and
+violates the desired property with a nonzero probability, this
+method essentially has a nonzero failure probability as well.
+Guo [13] achieves sub-linear regret almost surely by adopting
+a variant of ordinary least squares with annealing weight
+assigned to recent data, a parameter estimation algorithm
+convergent even with unstable trajectory data. However, the
+stronger convergence guarantee may come at the cost of less
+sharp asymptotic rate, and it is unclear whether the regret
+of this method can achieve
+˜O(
+√
+T) dependence on time.
+Wang et al. [11] achieves ˜O(
+√
+T) regret with a convergence-
+in-probability guarantee, via the use of a switched, rather
+than linear feedback controller, which falls back to a known
+stabilizing gain on the detection of large states. However,
+the controller design of this work does not rule out the
+frequent switching between the learned and fallback gains,
+a typical source of instability in switched linear systems [14],
+which restricts the correctness of their results to the case
+of commutative closed-loop system matrices. Moreover, the
+regret analysis in this work is not sufficiently refined to lead
+to almost sure guarantees.
+TABLE I: Comparison with selected existing
+works on adaptive LQR
+Work
+Rate
+Type of guarantee
+[13]
+Not provided
+Almost sure
+[6], [7], [9]
+˜
+O(
+√
+T)
+Probability 1 − δ
+[10]
+˜
+O(
+√
+T)
+Almost sure*
+[11]
+˜
+O(
+√
+T)
+Convergence in probability*
+This work
+˜
+O(
+√
+T)
+Almost sure
+* Requires non-standard assumptions; please refer to the
+main text for details.
+arXiv:2301.05537v1  [math.OC]  13 Jan 2023
+
+In this paper, we present an adaptive LQR controller with
+˜O(
+√
+T) regret almost surely, only assuming the availability
+of a known stabilizing feedback gain, which is a common
+assumption in the literature. This is achieved by a “circuit-
+breaking” mechanism motivated similarly as [11], which cir-
+cumvents safety breach by supervising the norm of the state
+and deploying the feedback gain when necessary. In contrast
+to [11], however, by enforcing a properly chosen dwell time on
+the fallback mode, the stability of the closed-loop system under
+our proposed controller is unaffected by switching. Another
+insight underlying our analysis is that the above mentioned
+circuit-breaking mechanism is triggered only finitely often.
+This fact implies that the conservativeness of the proposed
+controller, which prevents the system from being destabilized
+in the early stage and hence ensures the convergence of the
+system parameter estimates, may have negligible effect on
+the asymptotic performance of the system. Although similar
+phenomena have also been observed in [11], [15], we derive
+an upper bound on the time of the last trigger (Theorem 3,
+item 7)), a property missing from pervious works that paves
+the way to our almost sure regret guarantee.
+Outline
+The remainder of this manuscript is organized as follows:
+Section II introduces the problem setting. Section III describes
+the proposed controller. Section IV states and proves the
+theoretical properties of the closed-loop system under the pro-
+posed controller, and establishes the main regret upper bound.
+Section V validates the theoretical results using a numerical
+example. Finally, Section VI summarizes the manuscript and
+discusses directions for future work.
+Notations
+The set of nonnegative integers is denoted by N, and the
+set of positive integers is denoted by N∗. The n-dimensional
+Euclidean space is denoted by Rn, and the n-dimensional
+unit sphere is denoted by Sn. The n × n identity matrix is
+denoted by In. For a square matrix M, ρ(M) denotes the
+spectral radius of M, and tr(M) denotes the trace of M. For
+a real symmetric matrix M, M ≻ 0 denotes that M is positive
+definite. For any matrix M, M † denotes the Moore-Penrose
+inverse of M. For two vectors u, v ∈ Rn, ⟨u, v⟩ denotes
+their inner product. For a vector v, ∥v∥ denotes its 2-norm,
+and ∥v∥P = ∥P 1/2v∥ for P ≻ 0. For a matrix M, ∥M∥
+denotes its induced 2-norm, and ∥M∥F denotes its Frobenius
+norm. For a random vector x, x ∼ N(µ, Σ) denotes x is
+Gaussian distributed with mean µ and covariance Σ. For a
+random variable X, X ∼ χ2(n) denotes X has a chi-squared
+distribution with n degrees of freedom. P(·) denotes the
+probability operator, and E[·] denotes the expectation operator.
+For non-negative quantities f, g, which can be deterministic
+or random, we say f ≲ g to denote that f ≤ C1g+C2 for some
+universal constants C1 > 0 and C2 > 0, and f ≳ g to denote
+that g ≲ f. For a random function f(T) and a deterministic
+function g(T), we say f(T) = O(g(T)) to denote that
+lim supT →∞ f(T)/g(T) < ∞, and f(T) =
+˜O(g(T)) to
+denote that f(T) = O(g(T)(log(T))α) for some α > 0.
+II. PROBLEM FORMULATION
+This paper considers a fully observed discrete-time linear
+system with Gaussian process noise specified as follows:
+xk+1 = Axk + Buk + wk,
+k ∈ N∗,
+x1 = 0,
+(1)
+where xk ∈ Rn is the state, uk ∈ Rm is the control input,
+and wk
+i.i.d.
+∼
+N(0, W) is the process noise, where W ≻ 0.
+It is assumed without loss of generality that W = In, but all
+the conclusions apply to general positive definite W up to the
+scaling of constants. It is also assumed that the system and
+input matrices A, B are unknown to the controller, but (A, B)
+is controllable, and that the system is open-loop stable, i.e.,
+ρ(A) < 1. Consequently, there exists P0 ≻ 0 that satisfies the
+discrete Lyapunov equation
+A⊤P0A − P0 + Q = 0,
+(2)
+and there exists a scalar 0 < ρ0 < 1 such that
+A⊤P0A ≺ ρ0P0.
+(3)
+Remark 1. It has been commonly assumed in the liter-
+ature [9], [11] that (A, B) being stabilizable by a known
+feedback gain K0, i.e., ρ(A + BK0) < 1. In such case, the
+system can be rewritten as
+xk+1 = A′xk + Bu′
+k + wk,
+(4)
+where A′ = A + BK0, u′
+k = uk − K0xk, which reduces the
+problem to the case of open-loop stable systems. Therefore,
+we may assume without loss of generality that the system is
+open-loop stable, i.e., K0 = 0, for the simplicity of notations.
+The following average infinite-horizon quadratic cost is
+considered:
+J = lim sup
+T →∞
+1
+T E
+� T
+�
+k=1
+x⊤
+k Qxk + u⊤
+k Ruk
+�
+,
+(5)
+where Q ≻ 0, R ≻ 0 are fixed weight matrices specified by the
+system operator. It is well known that the optimal control law
+is the linear feedback control law of the form u(x) = K∗x,
+where the optimal feedback gain K∗ can be specified as:
+K∗ = −
+�
+R + B⊤P ∗B
+�−1 B⊤P ∗A,
+(6)
+and P ∗ is the unique positive definite solution to the discrete
+algebraic Riccati equation
+P ∗ = A⊤P ∗A − A⊤P ∗B
+�
+R + B⊤P ∗B
+�−1 B⊤P ∗A + Q.
+(7)
+The corresponding optimal cost is
+J∗ = tr
+�
+E
+�
+wkw⊤
+k
+�
+P ∗�
+= tr(WP ∗) = tr(P ∗).
+(8)
+The matrix P ∗ also satisfies the discrete Lyapunov equation
+(A + BK∗)⊤P ∗(A + BK∗) − P ∗ + Q + K⊤RK = 0, (9)
+which implies that there exists a scalar 0 < ρ∗ < 1 such that
+(A + BK∗)⊤P ∗(A + BK∗) ≺ ρ∗P ∗.
+(10)
+Since A, B are unknown to the controller in the considered
+setting, it is not possible to directly compute the optimal
+
+control law from (6) and (7). Instead, the controller learns the
+optimal control law online, whose performance is measured
+via the regret defined as follows:
+R(T) =
+T
+�
+k=1
+(x⊤
+k Qxk + u⊤
+k Ruk) − TJ∗.
+(11)
+The goal of the controller is to minimize the asymptotic growth
+of R(T).
+III. CONTROLLER DESIGN
+The logic of the proposed controller is presented in Algo-
+rithm 1. It can also be illustrated by the block diagram in
+Fig. 1. The remainder of this section would be devoted to
+explaining the components of the controller:
+Algorithm 1 Proposed controller
+1: ˆK0 ← 0
+2: ξ ← 0
+3: for k = 1, 2, . . . do
+4:
+Update parameter estimates ˆAk, ˆBk using (12)
+5:
+if ( ˆAk, ˆBk) is controllable then
+6:
+Update ˆKk from (6)-(7), replacing (A, B) with
+( ˆAk, ˆBk).
+7:
+else
+8:
+ˆKk ← 0
+9:
+uce
+k ← ˆKkxk
+10:
+if ξ = 0 then
+11:
+if ∥uce
+k ∥ > Mk := log(k) then
+12:
+ξ ← tk := ⌊log(k)⌋
+13:
+ucb
+k ← 0
+14:
+else
+15:
+ucb
+k ← uce
+k
+16:
+else
+17:
+ucb
+k ← 0
+18:
+ξ ← ξ − 1
+19:
+upr
+k ← k−1/4vk, where vk ∼ N(0, Im)
+20:
+Apply uk ← ucb
+k + upr
+k
+The proposed controller is a variant of the certainty equiv-
+alent controller [16], where the latter applies the input uce
+k =
+ˆKkxk, where the feedback gain ˆKk is calculated from (6)-
+(7) by treating the current estimates of the system parameters
+ˆAk, ˆBk as the true values. The differences of the proposed
+controller compared to the standard certainty equivalent con-
+troller is that i) it includes a “circuit-breaking” mechanism,
+which replace uce
+k
+with zero in certain circumstances; ii) it
+superposes the control input at each step with a probing noise
+upr
+k .
+The circuit-breaking mechanism replaces uce
+k
+with zero
+for the subsequent tk steps when the norm of the certainty
+equivalent control input ∥uce
+k ∥ exceeds a threshold Mk. The
+intuition behind this design is that a large certainty equivalent
+control input is indicative of having applied a destabilizing
+feedback gain recently, and circuit-breaking may prevent the
+state from exploding by leveraging the innate stability of the
+system, and hence help with the convergence of the parameter
+Circuit-
+breaking
+logic
+ξ > 0
+0
+ˆK
+uce
+ucb
++
+Plant
+(eq. (1))
+Estimator
+(eq. (7))
+ξ
+w
+upr
+u
+x
+ξ = 0
+Fig. 1: Block diagram of the closed-loop system under the
+proposed controller. The control input is the superposition of
+a deterministic input ucb and a random probing input upr. The
+deterministic part ucb is normally the same as the certainty
+equivalent input uce, but takes the value zero when circuit-
+breaking is triggered, where ξ is a counter for circuit-breaking.
+The certainty equivalent gain is updated using the parameter
+estimator in the meantime.
+estimator and the asymptotic performance of the controller.
+The threshold Mk is increased with the time index k, so
+that the “false alarm rate” of circuit-breaking, caused by the
+occasional occurrence of large noise vectors, decays to zero.
+The dwell time tk is also increased with time, in order to
+circumvent the potential oscillation of the system caused by
+the frequent switching between ˆK and 0 (c.f. [17]). Both Mk
+and tk are chosen to grow logarithmically with k, which would
+support our technical guarantees.
+Similarly to [9], [11], a probing noise upr
+k is superposed to
+the control input at each step to provide sufficient excitation
+to the system, which is required for the estimation of system
+parameters. Specifically, the probing noise is chosen to be
+upr
+k
+= k−1/4vk, where vk
+i.i.d.
+∼
+N(0, Im), which would
+correspond to the optimal rate of regret.
+The estimates of the system parameters ˆAk, ˆBk are up-
+dated using an ordinary least squares estimator. Denote Θ =
+[A
+B], ˆΘk
+= [ ˆAk
+ˆBk], and zk
+= [x⊤
+k
+u⊤
+k ]⊤, then
+according to xk+1 = Θzk, the ordinary least squares estimator
+can be specified as
+ˆΘk =
+�k−1
+�
+t=1
+xtz⊤
+t
+� �k−1
+�
+t=1
+ztz⊤
+t
+�†
+.
+(12)
+Remark 2. In the presented algorithm, the certainty equivalent
+gain is updated at every step k (see line 6 of Algorithm 1), but
+it may also be updated “logarithmically often” [11] (e.g., at
+steps k = 2i, i ∈ N∗), which is more computationally efficient
+in practice. It can be verified that all our theoretical results
+also apply to the case of logarithmically often updates.
+IV. MAIN RESULTS
+Underlying our analysis of the closed-loop system under the
+proposed controller are two random times, defined below:
+
+Tstab := inf
+�
+T
+���
+�
+Atk�⊤ P ∗Atk < ρP ∗,
+�
+A + B ˆKk
+�⊤
+P ∗ �
+A + B ˆKk
+�
+< ρP ∗, ∀k ≥ T
+�
+,
+(13)
+where ρ = (1 + ρ∗)/2, and tk is the dwell time defined in
+line 12 of Algorithm 1. And
+Tnocb := inf
+�
+T | ucb
+k ≡ uce
+k , ∀k ≥ T
+�
+.
+(14)
+With the above two random times, the evolution of the system
+can be divided into three stages:
+1) From the beginning to Tstab, the adaptive controller grad-
+ually refines its estimate of system parameters, and hence
+improves the performance of the certainty equivalent
+feedback gain, until the system becomes stabilized in the
+sense that there is a common Lyapunov function between
+the two modes under circuit-breaking as indicated in (13).
+2) From Tstab to Tnocb, the closed-loop system is stable as is
+ensured by the aforementioned common Lyapunov func-
+tion, and under mild regularity conditions on the noise,
+an upper bound on the magnitude certainty equivalent
+control input ∥uce
+k ∥ eventually drops below the circuit-
+breaking threshold Mk.
+3) From Tnocb on, circuit-breaking is not triggered any more,
+and the system behaves similarly as the closed-loop
+system under the optimal controller, with only small
+perturbations on the feedback gain which stem from the
+parameter estimation error and converge to zero.
+In the following theorem, we state several properties of the
+closed-loop system, based on which the above two random
+times are quantified:
+Theorem 3. Let n, m be the dimensions of the state and input
+vectors respectively, and P0, ρ0, P ∗, ρ∗ be defined in (2), (3),
+(7), (10) respectively. Then the following properties hold:
+1) For 0 < δ ≤ 1/2, the event
+Enoise(δ) :=
+�
+max{∥wk∥, ∥vk∥} ≤
+2
+√
+n + 1
+�
+log(k/δ), ∀k ∈ N∗�
+(15)
+occurs with probability at least 1 − 2δ.
+2) For 0 < δ ≤ 1/(8n2), the event
+Ecov(δ) :=
+������
+k
+�
+i=1
+(wiw⊤
+i − In)
+����� ≤
+7n
+√
+k log(8n2k/δ), ∀k ∈ N∗
+�
+(16)
+occurs with probability at least 1 − δ.
+3) On the event Enoise(δ), it holds
+∥xk∥ ≤ Cx log(k/δ), ∀k ∈ N∗,
+(17)
+where
+Cx = (∥B∥ + 1)(2√n + 1 + 1)∥P0∥∥P −1
+0
+∥
+1 − ρ1/2
+0
+.
+(18)
+4) For 0 < δ ≤ 1/6, the event
+Ecross(δ) :=
+������
+k
+�
+i=1
+w⊤
+i P ∗(Axi + Bucb
+i )
+����� ≤
+Ccross
+√
+k(log(k/δ))2, ∀k ∈ N∗
+�
+(19)
+occurs with probability at least 1 − 6δ, where
+Ccross = 4
+√
+n + 1∥P ∗∥(∥A∥Cx + ∥B∥).
+(20)
+5) For δ satisfying
+0 < δ < min
+�
+(800CV )−1, exp
+�
+24(m + n)1/3��
+,
+(21)
+the event
+Eest(δ) :=
+����ˆΘk − Θ
+���
+2
+≤ CΘk−1/2 log(k/δ),
+∀k ≥ k0
+�
+,
+(22)
+occurs with probability at least 1 − 6δ, where
+k0 = ⌈600(m + n) log(1/δ) + 5400⌉,
+(23)
+CV = Cx + 2
+√
+n + 1 + 1,
+(24)
+CΘ = (3200n/9)(5n/2 + 2).
+(25)
+6) On the event Eest(δ), it holds
+Tstab ≲ (log(1/δ))2.
+(26)
+7) On the event Enoise(δ) ∩ Eest(δ), for any α > 0, it holds
+Tnocb ≲ (1/δ)α.
+(27)
+Remark 4. The conclusions of Theorem 3 can be explained
+as follows:
+Items 1) and 2) defines two high-probability events on the
+regularity of noise. Item 3) bounds the state norm under regular
+noise, based on which item 4) bounds the growth of a cross
+term between noise and state that would be useful in regret
+analysis. Item 5) bounds the parameter estimation error, based
+on which item 6) bounds Tstab. Finally, item 7) states that
+the circuit-breaking mechanism is triggered only finitely, and
+bounds Tnocb, the time after which the circuit-breaking is not
+triggered any more.
+The following corollary characterizes the tail probabilities
+of Tstab and Tnocb, which follows directly from items 6) and
+7) of Theorem 3:
+Corollary 5. For Tstab defined in (13) and Tnocb defined
+in (14), as T → ∞, it holds
+1)
+P(Tstab ≥ T) = O(exp(−c
+√
+T)),
+(28)
+where c > 0 is a system-dependent constant.
+
+2) For any α > 0,
+P(Tnocb ≥ T) = O(T −α).
+(29)
+Building upon the properties stated in Theorem 3, a high-
+probability bound on the regret under the proposed controller
+can be ensured:
+Theorem 6. Given a failure probability δ, there exists a
+constant T0 ≲ (1/δ)1/4, such that for any fixed T > T0,
+it holds with probability at least 1 − δ that the regret defined
+in (11) satisfies
+R(T) ≲ (1/δ)1/4 +
+√
+T(log(T/δ))3.
+(30)
+As corollaries of Theorem 6, one can obtain a bound on the
+tail probability of R(T) (Theorem 7), and the main conclusion
+of this work, i.e., an almost sure bound on R(T) (Theorem 8):
+Theorem 7. For sufficiently large T, it holds
+P
+�
+R(T) ≥ CR
+√
+T(log(T))3�
+≤ 1
+T 2 ,
+(31)
+where CR is a system-dependent constant.
+Proof. The conclusion follows from invoking Theorem 6 with
+δ = 1/T 2.
+Theorem 8. It holds almost surely that
+R(T) = ˜O
+�√
+T
+�
+.
+(32)
+Proof. By Theorem 7, we have
+∞
+�
+T =1
+P
+�
+R(T) ≥ CR
+√
+T(log(T))3�
+< +∞.
+(33)
+By Borel-Cantelli lemma, it holds almost surely that the event
+�
+R(T) ≥ CR
+√
+T(log(T))3�
+(34)
+occurs finitely often, i.e.,
+R(T) = ˜O
+�√
+T
+�
+,
+a.s.
+(35)
+The remainder of this section is dedicated to proving
+Theorems 3 and 6.
+A. Proof of Theorem 3, item 1)
+Proof. Since wk ∼ N(0, In), it holds ∥wk∥ ∼ χ2(n). Apply-
+ing the Chernoff bound, for any a > 0, and any 0 < t < 1/2,
+it holds
+P(X ≥ a) ≤ E
+�
+etX/eta�
+= (1 − 2t)−n/2 exp(−ta).
+(36)
+Choosing t = 1/4, we have
+P(∥wk∥ ≥ a) ≤ 2n/2 exp(−a2/4)
+(37)
+for any k ∈ N∗ and a > 0. Invoking (37) with ak =
+2(log(ck2/δ))1/2, where c = 2n/2π2/6, we have
+∞
+�
+k=1
+P(∥wk∥ ≥ ak) ≤
+∞
+�
+k=1
+2n/2c−1δ/k2 = δ,
+(38)
+i.e., it holds with probability at least 1 − δ that
+∥wk∥ ≤ 2(log(ck2/δ))1/2 ≤ 2
+√
+n + 1
+�
+log(k/δ), ∀k ∈ N∗.
+(39)
+Similarly, it also holds with probability at least 1 − δ that
+∥vk∥ ≤ 2
+√
+n + 1
+�
+log(k/δ), ∀k ∈ N∗.
+(40)
+Combining (39) and (40) leads to the conclusion.
+B. Proof of Theorem 3, item 2)
+We start with a concentration bound on the sum of product
+of Gaussian random variables:
+Lemma 9. Let Xi
+i.i.d.
+∼
+N(0, 1), Yi
+i.i.d.
+∼
+N(0, 1), and
+{Xi}, {Yi} be mutually independent, then
+1) With probability at least 1 − 4δ,
+�����
+k
+�
+i=1
+X2
+i − k
+����� ≤ 7
+√
+k log(k/δ), ∀k ∈ N∗.
+(41)
+2) With probability at least 1 − 8δ,
+�����
+k
+�
+i=1
+XiYi
+����� ≤ 5
+√
+k log(k/δ), ∀k ∈ N∗.
+(42)
+Proof. Since �k
+i=1 X2
+i ∼ χ2(k), according to [18, Lemma 1],
+for any a > 0 and any k ∈ N∗, it holds
+P
+������
+k
+�
+i=1
+X2
+i − k
+����� ≥ 2√na + 2a
+�
+≤ 2 exp(−a).
+(43)
+Fix k and choose a = log(k2/δ), and it follows that with
+probability at least 1 − 2δ/k2,
+�����
+k
+�
+i=1
+X2
+i − k
+����� ≤ 2
+�
+k log(k2/δ) + 2 log(k2/δ)
+≤ 7
+√
+k log(k/δ).
+(44)
+Taking the union bound over k ∈ N∗, one can show that (41)
+holds with probability at least 1 − 2δ �∞
+k=1(1/k2) > 1 − 4δ,
+and hence claim 1) is proved.
+Since XiYi = (Xi+Yi)2/4+(Xi−Yi)2/4, and Xi+Yi
+i.i.d.
+∼
+N(0, 2), Xi−Yi
+i.i.d.
+∼ N(0, 2), claim 2) follows from applying
+claim 1) to {(Xi +Yi)/
+√
+2} and {(Xi −Yi)/
+√
+2} respectively
+and taking the union bound.
+Theorem 3, item 2) follows from the above lemma:
+Proof. Applying Lemma 9, item 1) to the diagonal elements,
+and Lemma 9, item 2) to the off-diagonal elements of
+�k
+i=1(wiw⊤
+i − I), and taking the union bound, one can show
+that with probability at least 1 − 8n2δ,
+k
+�
+i=1
+(wiw⊤
+i − In) ≤ 7
+√
+k log(k/δ),
+(45)
+
+where the inequality holds component-wise. Hence, with prob-
+ability at least 1 − 8n2δ,
+�����
+k
+�
+i=1
+(wiw⊤
+i − In)
+�����
+2
+≤
+�����
+k
+�
+i=1
+(wiw⊤
+i − In)
+�����
+2
+F
+≤ n2(7
+√
+k log(k/δ)),
+(46)
+and scaling the failure probability leads to the conclusion.
+C. Proof of Theorem 3, item 3)
+Proof. Notice
+xk = Ak−2d1 + Ak−3d2 + · · · + dk−1,
+(47)
+where dk = B(ucb
+k + upr
+k ) + wk. On Enoise(δ), it holds
+∥dk∥ ≤ ∥B∥ log(k) + 2(∥B∥ + 1)
+√
+n + 1
+�
+log(k/δ)
+≤ (∥B∥ + 1)(2
+√
+n + 1 + 1) log(k/δ).
+(48)
+Furthermore, from (2) and (47), it holds
+∥xk∥P ≤ ρ(k−2)/2
+0
+∥d1∥P + ρ(k−3)/2
+0
+∥d2∥P + · · · + ∥dk−1∥P
+≤
+1
+1 − ρ1/2
+0
+∥dk∥P ,
+(49)
+from which the conclusion follows.
+D. Proof of Theorem 3, item 4)
+This result is a corollary of a time-uniform version of
+Azuma-Hoeffding inequality [19], stated below:
+Lemma 10. Let {φk}k≥1 be a martingale difference sequence
+adapted to the filtration {Fk} satisfying |φk| ≤ dk a.s., then
+with probability at least 1 − 4δ, it holds
+�����
+k
+�
+i=1
+φi
+����� ≤ 2
+�
+�
+�
+�
+k
+�
+i=1
+d2
+i log(k/δ), ∀k.
+(50)
+Proof. By Azuma-Hoeffding inequality [19], for a fixed k, it
+holds with probability at least 1 − 2δ/k2 that
+�����
+k
+�
+i=1
+φi
+����� ≤
+�
+�
+�
+�2
+k
+�
+i=1
+d2
+i log(k2/δ) ≤ 2
+�
+�
+�
+�
+k
+�
+i=1
+d2
+i log(k/δ).
+(51)
+Taking the union bound over k ∈ N∗, one can prove that (50)
+holds with probability at least 1 − 2δ �∞
+k=1(1/k2) > 1 −
+4δ.
+Theorem 3, item 4) follows from the above lemma:
+Proof. According to Theorem 3, item 1), we only need to
+prove
+P(Ecross(δ) | Enoise(δ)) ≥ 1 − 4δ.
+(52)
+Therefore, we condition the remainder of the proof upon the
+event Enoise(δ). Let Fk be the σ-algebra generated by v1, w1,
+v2, w2, . . . , vk−1, wk−1, vk. Since xk ∈ Fk−1, ucb
+k ∈ Fk−1,
+E[wk | Fk−1] = 0 due to symmetry, it holds
+E
+�
+w⊤
+k P ∗ �
+Axk + Bucb
+k
+� ��Fk
+�
+=E [wk | Fk−1]⊤ P ∗ �
+Axk + Bucb
+k
+�
+= 0,
+(53)
+i.e., {w⊤
+k P ∗(Axk+Bucb
+k )} is a martingale difference sequence
+adapted to the filtration {Fk}. Furthermore, by Theorem 3,
+item 3, we have
+��w⊤
+k P ∗ �
+Axk + Bucb
+k
+���
+≤∥wk∥∥P ∗∥
+�
+∥A∥∥xk∥ + ∥B∥
+��ucb
+k
+���
+≤1
+2Ccross log(k/δ).
+(54)
+Hence, the conclusion follows from applying Lemma 10.
+E. Proof of Theorem 3, item 5)
+This subsection is devoted to deriving the time-uniform
+upper bound on estimation error stated in Theorem 3, item 5).
+Throughout this subsection, we denote Θ = [A
+B], ˆΘk =
+[ ˆAk
+ˆBk], zk = [x⊤
+k
+u⊤
+k ]⊤, and Vk = �k−1
+i=1 ziz⊤
+i .
+The proof can be split into three parts: firstly, we character-
+ize the estimation error ∥ˆΘk − Θ∥ in terms of the maximum
+and minimum eigenvalues of the regressor covariance matrix
+Vk, using a result in martingale least squares [5]. Secondly,
+an upper bound on the ∥Vk∥, which is a consequence of the
+non-explosiveness of states, can be derived as an corollary
+of Theorem 3, item 3). Finally, an upper bound on ∥V −1
+k
+∥,
+or equivalently a lower bound on the minimum eigenvalue
+of Vk, which is a consequence of sufficient excitation of the
+system, can be proved using an anti-concentration bound on
+block martingale small-ball (BMSB) processes [20]. The three
+parts would be discussed respectively below.
+1) Upper bound on least squares error, in terms of Vk:
+Lemma 11 ( [5, Corollary 1 of Theorem 3]). Let
+Sk =
+k
+�
+i=1
+ηimi−1, Uk =
+k
+�
+i=1
+mi−1m⊤
+i−1,
+(55)
+where {Fk}k∈N∗ is a filtration, {ηk}k∈N∗ is a random scalar
+sequence with ηk | Fk being conditionally σ2-sub-Gaussian,
+and {mk}k∈N∗ is a random vector sequence with mk ∈ Fk.
+Then with probability at least 1 − δ,
+∥Sk∥(U0+Uk)−1 ≤ 2σ2·
+log
+�
+det(U0)−1/2 det(U0 + Uk)1/2/δ
+�
+,
+∀k ∈ N∗, (56)
+where U0 ≻ 0 is an arbitrarily chosen constant positive semi-
+definite matrix.
+Proposition 12. With probability at least 1 − δ,
+���ˆΘk − Θ
+���
+2
+≤ 2n
+��V −1
+k
+��
+�
+log
+�n
+δ
+�
++ n
+2 log(1 + ∥Vk∥)
+�
+,
+∀k ≥ m + n + 1.
+(57)
+
+Proof. Let Fk be the σ-algebra generated by v1, w1, v2, w2,
+. . . , vk−1, wk−1, vk. From xk+1 = Θzk + wk, we have
+ˆΘk − Θ =
+�k−1
+�
+i=1
+wiz⊤
+i
+� �k−1
+�
+i=1
+ziz⊤
+i
+�†
+,
+(58)
+where wk|Fk ∼ N(0, In), zk ∈ Fk. With Vk = �k−1
+i=1 ziz⊤
+i ,
+we have Vi ≻ 0 a.s. for k ≥ m + n + 1. Now we can apply
+Lemma 11 to each row of ˆΘk − Θ: for each of j = 1, . . . , n,
+let Sj,k = �k−1
+i=1 (e⊤
+j wi)zi, where ej is the j-th standard unit
+vector. By invoking Lemma 11 with Uk = Vk and U0 = Im+n,
+we have: with probability at least 1 − δ,
+���e⊤
+j (ˆΘk − Θ)
+���
+2
+=
+��V −1
+k
+Sj,k
+�� ≤
+��V −1
+k
+�� ∥Sj,k∥(I+Vk)−1
+≤ 2
+��V −1
+k
+�� log
+�
+det(I + Vk)1/2/δ
+�
+≤ 2
+��V −1
+k
+��
+�
+log
+�1
+δ
+�
++ n
+2 log(1 + ∥Vk∥)
+�
+.
+(59)
+Taking the union bound over j = 1, . . . , n, we have: with
+probability at least 1 − nδ,
+���ˆΘk − Θ
+���
+2
+≤
+���ˆΘk − Θ
+���
+2
+F
+≤
+n
+�
+j=1
+���e⊤
+j (ˆΘk − Θ)
+���
+2
+≤2n
+��V −1
+k
+��
+�
+log
+�1
+δ
+�
++ n
+2 log(1 + ∥Vk∥)
+�
+.
+(60)
+Scaling the failure probability results in the conclusion.
+2) Upper bound on ∥Vk∥:
+Proposition 13. On the event Enoise(δ) defined in (15), it holds
+∥Vk∥ ≤ CV k(log(k/δ))2,
+(61)
+where CV is defined in (24).
+Proof. On Enoise(δ), we have
+∥uk∥ ≤ log(k) + 2
+√
+n + 1
+�
+log(k/δ),
+(62)
+and by Theorem 3, item 3), we have
+∥xk∥ ≤ Cx log(k/δ).
+(63)
+Hence,
+∥zk∥ ≤ ∥xk∥ + ∥uk∥ ≤
+�
+CV log(k/δ),
+(64)
+which implies
+∥Vk∥ ≤
+k−1
+�
+i=1
+∥zk∥2 ≤ CV k(log(k/δ))2.
+(65)
+3) Upper bound on ∥V −1
+k
+∥: We shall borrow the techniques
+of analyzing BMSB processes from Simchowitz et al. [20] to
+bound ∥V −1
+k
+∥. The BMSB process is defined as follows:
+Definition 14 ( [20, Definition 2.1]). Suppose that {φk}k∈N∗ is
+a real-valued stochastic process adapted to the filtration {Fk}.
+We say the process {φk} satisfies the (l, ν, p) block martingale
+small-ball (BMSB) condition if:
+1
+l
+l
+�
+i=1
+P (|φk+i| ≥ ν | Ft) ≥ p, ∀k ∈ N∗.
+(66)
+The following lemma verifies that {zk}, projected along an
+arbitrary direction, is BMSB:
+Lemma 15. For any µ ∈ Sm+n, the process {⟨zi, µ⟩}k−1
+i=1
+satisfies the (1, k−1/4, 3/10) BMSB condition.
+Proof. Let Fk be the σ-algebra generated by v1, w1, v2, w2,
+. . . , vk−1, wk−1, vk. Since
+zi =
+�xi
+ui
+�
+=
+�
+xi
+ucb
+i + upr
+i
+�
+,
+(67)
+and xi+1 = Aixt + Bupr
+i
++ wi, where Ai takes value from
+{A, A + B ˆKi} and belongs to Fi, we have
+|⟨zi+1, µ⟩| = |⟨xi+1, µ1⟩ + ⟨ucb
+i+1, µ2⟩ + ⟨upr
+i+1, µ2⟩|
+≥ |⟨Aixi + Bupr
+i + wi, µ1⟩ + ⟨upr
+i+1, µ2⟩|
+=
+����
+� �Aixi + Bupr
+i + wi
+upr
+i+1
+�
+, µ
+����� ,
+(68)
+where µ1 = [In
+0]µ, µ2 = [0
+Im]µ. Therefore, we only
+need to verify
+P
+�����
+� �Aixi + Bupr
+i + wi
+upr
+i+1
+�
+, µ
+����� ≥ k−1/4���Fi
+�
+≥ 3
+10. (69)
+Since Aixi ∈ Fi, and upr
+i
+| Fi, wi | Fi, upr
+i+1 | Fi are all
+Gaussian,
+� �Aixi + Bupr
+i + wi
+upr
+i+1
+�
+, µ
+�
+,
+(70)
+as an affine function of the above terms, is also Fi-
+conditionally Gaussian, whose mean and variance are:
+E
+�� �Aixi + Bupr
+i + wi
+upr
+i+1
+�
+, µ
+����� Fi
+�
+= ⟨Aixi, µ1⟩,
+E
+��� �Aixi + Bupr
+i + wi
+upr
+i+1
+�
+, µ
+�
+− ⟨Aixi, µ1⟩
+�2����� Fi
+�
+= E
+�� �Bupr
+i + wi
+upr
+i+1
+�
+, µ
+�2���� Fi
+�
+= µT
+�
+i−1/2BB⊤ + I
+0
+0
+(i + 1)−1/2
+�
+µ
+≥ µT
+�I
+0
+0
+k−1/2
+�
+µ ≥ k−1/2.
+(71)
+The conclusion (69) then follows from the fact that for any
+X ∼ N(µ, σ2), it holds P(|X| ≥ σ) ≥ P(|X − µ| ≥ σ) ≥
+3/10.
+An upper bound on ∥V −1
+k
+∥ can be obtained by applying an
+anti-concentration property of BMSB, along with a covering
+argument in [20]:
+
+Lemma 16. For any fixed k ≥ 2 and 0 < δk ≤ 1/2, it holds
+P
+���V −1
+k
+�� ≥ 1600
+9
+k−1/2
+�
+≤
+δk + e−
+9
+800 k+(m+n) log(800CV k1/2(log(k/δk))2),
+(72)
+where CV is defined in Theorem 3, item 5).
+Proof. Firstly, for any fixed µ ∈ Sm+n, applying [20, Prop.
+2.5] to the process {⟨zi, µ⟩}k−1
+i=1 , which is (1, k−1/4, 3/10)-
+BMSB by Lemma 15, we have
+P
+�k−1
+�
+i=1
+⟨zi, µ⟩2 ≤ k−1/2(3/10)2
+8
+k
+�
+≤ e− (3/10)2k
+8
+,
+(73)
+i.e.,
+P
+�
+µ⊤Vkµ ≤
+9
+800k1/2
+�
+≤ e−
+9
+800 k.
+(74)
+Next, we shall choose multiple µ’s and using a covering
+argument to lower bound the minimum eigenvalue of Vk, and
+hence to upper bound ∥V −1
+k
+∥: let Γ = CV k(log(k/δk))2Im+n,
+and Γ = (9/800)k1/2Im+n. Let T be a minimal 1/4-net of
+SΓ in the norm ∥ · ∥Γ, then by [20, Lemma D.1], we have
+log |T | ≤ (m + n) log(9) + log det(ΓΓ−1)
+≤ (m + n) log(800CV k1/2(log(k/δk))2).
+(75)
+According to (74) and (75), we have
+P
+�
+µ⊤Vkµ ≤
+9
+800k1/2, ∀µ ∈ T
+�
+≤ |T |e−
+9
+800 k
+≤ e−
+9
+800 k+(m+n) log(800CV k1/2(log(k/δk))2).
+(76)
+On the other hand, according to Proposition 13 and Theorem 3,
+item 1), we have
+P
+�
+∥Vk∥ ≤ CV k(log(k/δk))2�
+≤ δk,
+(77)
+From (76), (77) and [20, Lemma D.1], it follows that
+P (Vk ≻ Γ/2) is no greater than the RHS of (72), which is
+equivalent to the conclusion.
+The next proposition converts Lemma 16 into a time-
+uniform bound:
+Proposition 17. For δ satisfying (21) and k0 defined in (23),
+it holds
+P
+���V −1
+k
+�� ≤ 1600
+9
+k−1/2, ∀k ≥ k0
+�
+≤ 3δ.
+(78)
+Proof. For k ≥ k0, with δk = δ/k2, it holds
+k ≥ (1300(m + n))4/3 ,
+(79)
+and hence,
+(m + n) log(800CV k1/2(log(k/δk))2)
+≤(m + n)
+�
+3 log(1/δ) + 13
+2 log(k)
+�
+≤ 1
+200k + 13
+2 (m + n)k1/4 ≤
+1
+100k.
+(80)
+Substituting (80) into (72), we have
+P
+���V −1
+k
+�� ≥ 1600
+9
+k−1/2
+�
+≤ δ
+k2 + e−
+1
+800 k.
+(81)
+Taking the union bound over k = k0, k0 + 1, . . ., we have
+P
+���V −1
+k
+�� ≥ 1600
+9
+k−1/2, ∀k ≥ k0
+�
+≤π2
+6 δ + 801e−
+1
+800 k0 ≤ 3δ.
+(82)
+Theorem 3, item 5) follows from Propositions 12, 13 and
+17.
+F. Proof of Theorem 3, item 6)
+Proof. Let
+T1 = inf
+�
+T
+���
+�
+Atk�⊤ P ∗Atk < ρP ∗, ∀k ≥ T
+�
+,
+(83)
+T2 = inf
+�
+T
+����
+�
+A + B ˆKk
+�⊤
+P ∗ �
+A + B ˆKk
+�
+< ρP ∗,
+∀k ≥ T
+�
+.
+(84)
+We shall bound T1 and T2 respectively:
+1) From the assumption ρ(A) < 1, it holds
+lim
+k→∞
+�
+Ak�⊤ PAk = 0,
+(85)
+which, together with tk = ⌊log(k)⌋, implies T1 is a finite
+constant independent of δ, i.e., T1 ≲ 1.
+2) Since (A + BK)⊤P ∗(A + BK) is a continuous function
+of K, from (10), there exists a system-dependent con-
+stant ϵK, such that (A + BK)⊤P ∗(A + BK) < ρP ∗
+whenever ∥K − K∗∥ < ϵK. On the other hand, since
+ˆKk is a continuous function of ˆΘk [9, Proposition 6],
+there exists a system-dependent constant ϵΘ, such that
+∥ ˆK − K∗∥ < ϵK as long as ∥ˆΘk − Θ∥ < ϵΘ. It follows
+from Theorem 3, item 5) that ∥ˆΘk − Θ∥ < ϵΘ whenever
+k ≥ (9C2
+Θ/ϵ2
+Θ)(log(1/δ))2, and hence T2 ≲ (log(1/δ))2.
+In summary, it holds Tstab = max{T1, T2} ≲ (log(1/δ))2.
+G. Proof of Theorem 3, item 7)
+This subsection is dedicated to bounding the time after
+which the circuit-breaking is not triggered any more. The
+outline of the proof is stated as follows: firstly, we define
+a subsequence notation to deal with the dwell time tk of
+circuit breaking. Secondly, an upper bound on the state and
+the certainty equivalent input after Tstab is derived, which is
+shown to be asymptotically smaller than the circuit-breaking
+threshold Mk = log(k). Based on the above upper bound on
+the certainty equivalent input, we can finally bound Tnocb, i.e.,
+the time it takes for the certainty equivalent input to stay below
+the threshold Mk, which leads to the desired conclusion.
+
+1) A subsequence notation: Consider the subsequence of
+states and inputs, where steps within the circuit-breaking
+period are skipped, defined below:
+i(1) = 1, i(k + 1) =
+�
+i(k) + 1
+ucb
+i(k) ̸= 0
+i(k) + ti(k)
+ucb
+i(k) = 0 ,
+(86)
+˜xk = xi(k), ˜uce
+k = uce
+i(k), ˜ucb
+k = ucb
+i(k).
+(87)
+Consider Tstab defined in (13). We can define ˜Tstab as the
+first index in the above subsequence for which the stabilization
+condition is satisfied, i.e.,
+˜Tstab = inf{T | i(T) ≥ Tstab}.
+(88)
+2) Upper bound on state and certainty equivalent input
+after Tstab:
+Proposition 18. On the event Enoise(δ) ∩ Eest(δ), it holds
+��˜x ˜Tstab+k
+�� ≲ ρk/2 log(1/δ) +
+�
+log(k/δ),
+(89)
+���˜uce
+˜Tstab+k
+��� ≲ ρk/2 log(1/δ) +
+�
+log(k/δ),
+(90)
+where ρ = (1 + ρ∗)/2.
+Proof. We can expand ˜x ˜Tstab+k as:
+˜x ˜Tstab+k = ˜A ˜Tstab+k−1 ˜A ˜Tstab+k−2 · · · ˜A ˜Tstab ˜x ˜Tstab+
+˜A ˜Tstab+k−1 ˜A ˜Tstab+k−2 · · · ˜A ˜Tstab+1 ˜w ˜Tstab+
+· · · +
+˜w ˜Tstab+k−1,
+(91)
+where:
+• ˜Aj ∈ {A + B ˆKi(j), Ati(j)}, and must satisfy ˜A⊤
+j P ˜Aj <
+ρP for j ≥ ˜Tstab, by definition of ˜Tstab in (13);
+• ˜wj ∈ {wi(j), �ti(j)−1
+τ=0
+Aτwi(j−1)+τ}, and on the event
+Enoise(δ), it must satisfy ∥ ˜wj∥
+≲
+A
+�
+log(j/δ)
+≲
+�
+log(j/δ) for any j, where A = �∞
+τ=0 ∥Aτ∥.
+Combining the above two items, we have
+��˜x ˜Tstab+k
+�� ≲ ρk/2 ��˜x ˜Tstab
+�� +
+�
+log
+�
+i
+�
+˜Tstab + k
+�
+/δ
+�
+. (92)
+We shall next bound
+��˜x ˜Tstab
+�� and i( ˜Tstab + k) respectively:
+1) According to the definition of ˜Tstab and i(·) in (86)
+and (88), we have
+i
+�
+˜Tstab
+�
+≤ Tstab + log(Tstab).
+(93)
+On Eest(δ), according to Theorem 3, item 6, we have
+Tstab ≲ (log(1/δ))2, and hence
+i
+�
+˜Tstab
+�
+≲ (log(1/δ))2 + log((log(1/δ))2)
+≲ (log(1/δ))2.
+(94)
+Furthermore, according to Theorem 3, item 3, on
+Enoise(δ), we have ∥xk∥ ≲ log(k/δ) for any k, and hence
+��˜x ˜Tstab
+�� =
+���xi( ˜Tstab)
+��� ≲ log
+�(log(1/δ))2
+δ
+�
+= log(1/δ) + log((log(1/δ))2) ≲ log(1/δ).
+(95)
+2) By definition of i(·) in (86), we have
+i
+�
+˜Tstab + k + 1
+�
+≤ ˜Tstab +k+log
+�
+˜Tstab + k
+�
+, ∀k ∈ N∗.
+(96)
+Applying induction to (93) and (96), we can obtain
+i
+�
+˜Tstab + k
+�
+≲ k log(Tstabk) + Tstab.
+(97)
+Substituting Tstab ≲ (log(k/δ))2, which holds on Eest(δ)
+according to Theorem 3, item 6), into (97), we have
+i
+�
+˜Tstab + k
+�
+≲ k(log(k/δ))2.
+(98)
+Hence, inequality (89) follows from substituting (95) and
+(98) into (92). Moreover, since
+��� ˆKi( ˜Tstab+k)
+��� is uniformly
+bounded by definition of Tstab in (13), we have
+���˜uce
+˜Tstab+k
+��� ≤
+��� ˆKi( ˜Tstab+k)
+���
+��˜x ˜Tstab+k
+�� ≲
+��˜x ˜Tstab+k
+�� ,
+(99)
+which implies (90).
+3) Upper bound on Tnocb: Now we are ready to prove
+Theorem 3, item 7):
+Proof. For any ϵ > 0, according to (98), we have i( ˜Tstab+k) ≲
+(1/δ)α+ϵ as long as k ≲ (1/δ)α−ϵ. Hence, we only need to
+prove
+ucb
+k ≡ uce
+k ,
+∀k ≥ i
+�
+˜Tstab + k0
+�
+,
+(100)
+for some k0 ≲ (1/δ)α−ϵ.
+Notice that (100) is equivalent to
+˜ucb
+˜Tstab+k ≡ ˜uce
+˜Tstab+k,
+∀k ≥ k0,
+(101)
+which is then equivalent to
+���˜uce
+˜Tstab+k
+��� ≤ Mk = log(k),
+∀k ≥ k0.
+(102)
+According to Proposition 18, we only need to verify
+ρk/2 log(1/δ) +
+�
+log(k/δ) ≲ log(k),
+(103)
+whenever k ≳ (1/δ)α−ϵ. In such case, we have
+ρk/2 log(1/δ) +
+�
+log(k/δ)
+≲ log(1/δ) +
+�
+log(k) + log(1/δ)
+≲ log(k) +
+�
+log(k) ≲ log(k),
+(104)
+from which the conclusion follows.
+H. Proof of Theorem 6
+In this subsection, we first decompose the regret of the
+proposed controller into multiple terms, then derive upper
+bounds on the terms respectively to obtain the high-probability
+regret bound stated in Theorem 6.
+
+1) Regret decomposition:
+We first state a supporting
+lemma:
+Lemma 19. Let K∗, P ∗ be defined in (6), (7) respectively,
+and K = K∗ + ∆K, then
+Q + K⊤RK + (A + BK)⊤ P ∗ (A + BK) − P ∗
+=∆K⊤(R + B⊤P ∗B)∆K.
+(105)
+Proof. Substituting the Lyapunov equation (9) into the LHS
+of (105), we have
+Q + K⊤RK + (A + BK)⊤P ∗(A + BK) − P ∗
+=K⊤RK − (K∗)⊤ RK∗ + (A + BK)⊤P ∗(A + BK)−
+(A + BK∗)⊤ P ∗ (A + BK∗)
+=∆K⊤ �
+R + B⊤P ∗B
+�
+∆K + G + G⊤,
+(106)
+where
+G = ∆K⊤ �
+(R + B⊤P ∗B)K∗ + B⊤P ∗A
+�
+.
+(107)
+By definition of K∗ in (6), we have G = 0, and hence the
+conclusion holds.
+Now we are ready to state the decomposition of regret:
+Proposition 20. The regret of the proposed controller defined
+in (11) can be decomposed as
+R(T) =
+7
+�
+i=1
+Ri(T),
+(108)
+with the terms Ri(T) defined as:
+R1(T) =
+T
+�
+k=1
+x⊤
+k (Kk − K∗)⊤(R + BT P ∗B)(Kk − K∗)xk,
+(109)
+R2(T) = 2
+T
+�
+k=1
+(upr
+k )⊤ B⊤P ∗(A + BKk)xk,
+(110)
+R3(T) = 2
+T
+�
+k=1
+w⊤
+k P ∗(A + BKk)xk,
+(111)
+R4(T) =
+T
+�
+k=1
+(s⊤
+k P ∗sk − w⊤
+k P ∗wk),
+(112)
+R5(T) =
+T
+�
+k=1
+w⊤
+k P ∗wk − TJ∗,
+(113)
+R6(T) = x⊤
+1 P ∗x1 − x⊤
+T +1P ∗xT +1,
+(114)
+R7(T) =
+T
+�
+k=1
+2 (upr
+k )⊤ Rucb
+k + (upr
+k )⊤ Rupr
+k ,
+(115)
+where Kk, sk are defined as:
+Kk =
+� ˆKk
+ucb
+k = uce
+k
+0
+otherwise , sk = Bupr
+k + wk.
+(116)
+Proof. From uk = ucb
+k + upr
+k = Kkxk + upr
+k , it holds
+R(T) =
+T
+�
+k=1
+�
+x⊤
+k Qxk + u⊤
+k Ruk
+�
+− TJ∗
+=
+T
+�
+k=1
+�
+x⊤
+k
+�
+Q + K⊤
+k RKk
+�
+xk + 2 (upr
+k )⊤ Rucb
+k +
+(upr
+k )⊤ Rupr
+k
+�
+− TJ∗
+=
+T
+�
+k=1
+�
+x⊤
+k
+�
+Q + K⊤
+k RKk
+�
+xk + x⊤
+k+1P ∗xk+1−
+x⊤
+k P ∗xk
+�
+− TJ∗ + R6(T) + R7(T).
+(117)
+We can further expand the summands in the RHS of the above
+inequality: from xk+1 = (A + BKk)xk + sk, we have
+x⊤
+k
+�
+Q + K⊤
+k RKk
+�
+xk + x⊤
+k+1P ∗xk+1 − x⊤
+k P ∗xk
+=x⊤
+k
+�
+Q + K⊤
+k RKk + (A + BKk)⊤P ∗(A + BKk) − P ∗�
+xk
++ 2s⊤
+k P ∗(A + BKk)xk + s⊤
+k P ∗sk
+=x⊤
+k (Kk − K∗)⊤(R + B⊤P ∗B)(Kk − K∗)xk+
+2s⊤
+k P ∗(A + BKk)xk + s⊤
+k P ∗sk,
+(118)
+where the last equality follows from Lemma 19. It follows
+from simple algebra that
+T
+�
+k=1
+�
+x⊤
+k
+�
+Q + K⊤
+k RKk
+�
+xk + x⊤
+k+1P ∗xk+1 − x⊤
+k P ∗xk
+�
+− TJ∗
+=
+5
+�
+i=1
+Ri(T),
+(119)
+and hence the conclusion follows.
+2) Upper bound on regret terms: Next we shall bound the
+terms Ri(T) (i = 1, . . . , 8) respectively:
+Proposition 21. The regret terms defined in (109)-(115) can
+be bounded as follows:
+1) On the event Enoise(δ) ∩ Eest(δ), for T > Tnocb, it holds
+R1(T) ≲ (1/δ)1/4(log(1/δ))4+
+√
+T(log(T/δ))3. (120)
+2) On the event Enoise(δ), it holds
+|R2(T)| ≲
+√
+T(log(T/δ))3/2.
+(121)
+3) On the event Ecross(δ), it holds
+|R3(T)| ≲
+√
+T(log(T/δ))2.
+(122)
+4) On the event Enoise(δ), it holds
+|R4(T)| ≤
+√
+T log(T/δ).
+(123)
+5) On the event Ecov(δ), it holds
+|R5(T)| ≲
+�
+T log(1/δ).
+(124)
+6) On the event Enoise(δ), it holds
+|R6(T)| ≲ (log(T/δ))2.
+(125)
+7) On the event Enoise(δ), it holds
+|R7(T)| ≲
+√
+T log(T/δ).
+(126)
+
+Proof.
+1) Let
+r1k = x⊤
+k (Kk − K∗)⊤ �
+R + B⊤P ∗B
+�
+(Kk − K∗)xk.
+(127)
+We shall next bound �Tnocb
+k=1 r1k and �T
+k=Tnocb+1 r1k re-
+spectively:
+a) For k ≤ Tnocb, we have ∥xk∥ ≲ log(k/δ) by The-
+orem 3, item 3), and ∥Kkxk∥ = ∥ucb
+k ∥ ≤ log(k).
+Therefore, it holds
+r1k ≲ (log(k/δ))2,
+(128)
+and hence,
+Tnocb
+�
+k=1
+r1k ≲ Tnocb(log(Tnocb/δ))2.
+(129)
+Invoking Theorem 3, item 7 with α = 1/4, we get
+Tnocb
+�
+k=1
+r1k ≲ (1/δ)1/4(log(1/δ))4.
+(130)
+b) For k ≤ Tnocb, by definition of Tnocb, we have Kk =
+ˆKk. Hence, by definition of Eest and the fact that ˆKk
+is a continuous function of ˆΘk [9, Proposition 6], we
+have
+∥Kk − K∗∥ =
+��� ˆKk − K∗���
+≲
+���ˆΘk − Θ
+��� ≲ k−1/4(log(k/δ))1/2.
+(131)
+Furthermore, by Theorem 3, item 3, we have ∥xk∥ ≲
+log(k/δ), and hence,
+r1k ≲ ∥Kk−K∗∥2∥xk∥2 ≲ k−1/2(log(k/δ))3. (132)
+Therefore,
+T
+�
+k=Tnocb+1
+r1k ≲
+√
+T(log(T/δ))3.
+(133)
+Summing up (130) and (133) leads to (120).
+2) Let
+r2k = (upr
+k )⊤ B⊤P ∗(A + BKk)xk,
+(134)
+whose factors can be bounded as follows:
+• ∥upr
+k ∥ = k1/2∥vk∥ ≲ k−1/2(log(k/δ))1/2 by defini-
+tion of Enoise;
+• ∥xk∥ ≲ log(k/δ) by Theorem 3, item 3);
+• ∥Kkxk∥ =
+��ucb
+k
+�� ≤ Mk = log(k) according to the
+proposed controller.
+Hence,
+|r2k| ≲ k−1/2(log(k/δ))3/2,
+(135)
+and summing up (135) from k = 1 to T leads to (121).
+3) The inequality (122) follows directly from the definition
+of Ecross(δ) in (19).
+4) Let
+r4k = s⊤
+k P ∗sk − w⊤
+k P ∗wk.
+(136)
+From sk = wk + Bupr
+k = wk + k−1/2Bvk, we have
+r4k = 2k−1/2w⊤
+k P ∗Bvk + k−1v⊤
+k B⊤P ∗Bvk.
+(137)
+Hence, by definition of Enoise(δ), we have
+|r4k| ≲ k−1/2 log(k/δ).
+(138)
+Summing up (138) from k = 1 to T leas to (123).
+5) Since J∗ = tr(P ∗) (see (8)), we have
+|R5(T)| =
+�����
+T
+�
+k=1
+tr(wkw⊤
+k P) − T tr(P)
+�����
+=
+�����tr
+�� T
+�
+k=1
+(wkw⊤
+k − In)
+�
+P
+������
+≲
+�����
+T
+�
+k=1
+(wkw⊤
+k − In)
+����� ≲
+�
+T log(1/δ), (139)
+where the last inequality follows from the definition of
+Ecov(δ), which proves (124).
+6) The inequality (125) is a direct corollary of Theorem 3,
+item 3).
+7) Let
+r7k = 2 (upr
+k )⊤ Rucb
+k + (upr
+k )⊤ Rupr
+k ,
+(140)
+where upr
+k and ucb
+k satisfy:
+• ∥upr
+k ∥ = k−1/2∥vk∥ ≲ k−1/2(log(k/δ))1/2 by defini-
+tion of Enoise(δ);
+•
+��ucb
+k
+�� ≤ Mk = log(k) according to the proposed
+controller.
+Hence,
+|r7k| ≲ k−1/2 log(k/δ),
+(141)
+and summing up (141) from k = 1 to T leads to (126).
+Theorem 6 follows from combining Propositions 20 and 21.
+V. SIMULATION
+In this section, the proposed controller is validated on
+the Tennessee Eastman Process (TEP) [21]. In particular, we
+consider a simplified version of TEP similar to the one in [22],
+with full state feedback. The system is open-loop stable, and
+has state dimension n = 8 and input dimension m = 4. The
+process noise distribution is chosen to be wk
+i.i.d.
+∼
+N(0, In).
+The weight matrices of LQR are chosen to be Q = In and
+R = Im. The plant under the proposed controller is simulated
+for 10000 independent trials, each with T = 3 × 108 steps.
+As mentioned in Remark 2, the certainty equivalent gain ˆKk
+is updated only at steps k = 2i, i ∈ N∗ for the sake of fast
+computation.
+The evolution of regret against time is plotted in Fig. 2.
+For the ease of observation, we plot the relative average
+regret R(T)/(TJ∗) against the total time step T, where J∗
+is the optimal cost. Fig. 2 shows 5 among the 10000 trials,
+from which one can observe a 1/
+√
+T convergence rate of the
+relative average regret (i.e., a 1 order-of-magnitude increase
+in T corresponds to a 0.5 order-of-magnitude decrease in
+R(T)/(TJ∗)), which matches the
+√
+T theoretical growth rate
+of regret. To inspect the statistical properties of all the trials,
+we sort them by the average regret at the last step, and plot
+
+the worst, median and mean cases in Fig. 2b. One can observe
+that the average regret converge to zero even in the worst case,
+which validates the almost-sure guarantee in Theorem 8.
+102
+103
+104
+105
+106
+107
+108 3 × 108
+10−2.5
+10−2.0
+10−1.5
+10−1.0
+10−0.5
+100.0
+100.5
+Total time step T
+R(T)/(TJ∗)
+(a) Five random sample paths
+102
+103
+104
+105
+106
+107
+108 3 × 108
+10−5
+10−4
+10−3
+10−2
+10−1
+100
+Total time step T
+R(T)/(TJ∗)
+Worst
+Median
+Best
+(b) Worst, median and best cases among all sample paths
+Fig. 2: Double-log plot of average regret against time step
+An insight to behold on the performance of the proposed
+controller is that the circuit-breaking mechanism is triggered
+only finitely, and the time of the last trigger Tnocb, as stated
+in Corollary 5, has a super-polynomial tail. This insight is
+also empirically validated: among all the 10000 trials, circuit-
+breaking is never triggered after step 1.4×106, and a histogram
+of Tnocb is shown in Fig. 3, from which one can observe that
+the empirical distribution of Tnocb has a fast decaying tail.
+2
+4
+6
+8
+10
+12
+14
+0
+200
+400
+600
+800
+1000
+1200
+Tnocb(×105)
+Frequency
+Fig. 3: Histogram of Tnocb among all sample paths
+VI. CONCLUSION
+In this paper, we propose an adaptive LQR controller that
+can achieve ˜O(
+√
+T) regret almost surely. A key underlying
+the controller design is a circuit-breaking mechanism, which
+ensures the convergence of the parameter estimate, but is
+triggered only finitely often and hence has negligible effect
+on the asymptotic performance. A future direction would be
+extending such circuit-breaking mechanism to the partially
+observed LQG setting.
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+
diff --git a/CNE5T4oBgHgl3EQfTg-d/content/tmp_files/load_file.txt b/CNE5T4oBgHgl3EQfTg-d/content/tmp_files/load_file.txt
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@@ -0,0 +1,606 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf,len=605
+page_content='Almost Surely  √  T Regret Bound for Adaptive LQR  Yiwen Lu and Yilin Mo  Abstract—The Linear-Quadratic Regulation (LQR) problem  with unknown system parameters has been widely studied, but it  has remained unclear whether ˜O(  √  T) regret, which is the best  known dependence on time, can be achieved almost surely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In  this paper, we propose an adaptive LQR controller with almost  surely  ˜O(  √  T) regret upper bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The controller features a  circuit-breaking mechanism, which circumvents potential safety  breach and guarantees the convergence of the system parameter  estimate, but is shown to be triggered only finitely often and  hence has negligible effect on the asymptotic performance of  the controller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The proposed controller is also validated via  simulation on Tennessee Eastman Process (TEP), a commonly  used industrial process example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' INTRODUCTION  Adaptive control, the study of decision-making under the  parametric uncertainty of dynamical systems, has been pur-  sued for decades [1]–[4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Although early research mainly  focused on the the aspect of convergence and stability, recent  years have witnessed significant advances in the quantitative  performance analysis of adaptive controllers, especially for  multivariate systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In particular, in the adaptive Linear-  Quadratic Regulation (LQR) setting considered in this paper,  the controller attempts to solve the stochastic LQR problem  without access to the true system parameters, and its perfor-  mance is evaluated via regret, the cumulative deviation from  the optimal cost over time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' This adaptive LQR setting has  been widely studied in the past decade [5]–[11], but it has  remained unclear whether adaptive controllers for LQR can  achieve ˜O(  √  T) regret, whose asymptotic dependence on the  time T is the best known (up to poly-logarithmic factors) 1,  almost surely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Existing regret upper bounds on adaptive LQR, summarized  in Table I, are either weaker than almost-sure in terms of  the type of probabilistic guarantee, or suboptimal in terms of  asymptotic dependence on time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' By means of optimism-in-  face-of-uncertainty [7], Thompson sampling [6], or ϵ-greedy  algorithm [9], an ˜O(  √  T) regret can be achieved with proba-  bility at least 1 − δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In other words, these algorithms may not  converge to the optimal one or could even be destablizing  with a non-zero probability δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In practice, such a failure  probability may hinder the application of these algorithms in  safety-critical scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' From a theoretical perspective, we  argue that it is highly difficult to extend these algorithms  to provide stronger performance guarantees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' To be specific,  The  authors  are  with  the  Department  of  Automa-  tion  and  BNRist,  Tsinghua  University,  Beijing,  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Emails:  luyw20@mails.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='tsinghua.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='cn,  ylmo@tsinghua.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='cn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  1It is known that  √  T is the optimal L1 rate of regret [9], and we suspect  that it is also the optimal almost sure rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  despite different exploration strategies, the aforementioned  methods all compute the control input using a linear feedback  gain synthesized from a least-squares estimate of system  parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Due to Gaussian process noise, the derived linear  feedback gain may be destabilizing, regardless of the amount  of data collected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For these algorithms, the probability of such  catastrophic event is bounded by a positive δ > 0, which is a  predetermined design parameter and cannot be changed during  online operation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Alternative methods that may preclude the above de-  scribed failure probability include introducing additional sta-  bility assumptions, using parameter estimation algorithms with  stronger convergence guarantees, and adding a layer of safe-  guard around the linear feedback gain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Faradonbeh et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' [10]  achieves ˜O(  √  T) regret almost surely under the assumption  that the closed-loop system remains stable all the time, based  on a stabilization set obtained from adaptive stabilization [12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Since the stabilization set is estimated from finite data and  violates the desired property with a nonzero probability, this  method essentially has a nonzero failure probability as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Guo [13] achieves sub-linear regret almost surely by adopting  a variant of ordinary least squares with annealing weight  assigned to recent data, a parameter estimation algorithm  convergent even with unstable trajectory data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' However, the  stronger convergence guarantee may come at the cost of less  sharp asymptotic rate, and it is unclear whether the regret  of this method can achieve  ˜O(  √  T) dependence on time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' [11] achieves ˜O(  √  T) regret with a convergence-  in-probability guarantee, via the use of a switched, rather  than linear feedback controller, which falls back to a known  stabilizing gain on the detection of large states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' However,  the controller design of this work does not rule out the  frequent switching between the learned and fallback gains,  a typical source of instability in switched linear systems [14],  which restricts the correctness of their results to the case  of commutative closed-loop system matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Moreover, the  regret analysis in this work is not sufficiently refined to lead  to almost sure guarantees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  TABLE I: Comparison with selected existing  works on adaptive LQR  Work  Rate  Type of guarantee  [13]  Not provided  Almost sure  [6], [7], [9]  ˜  O(  √  T)  Probability 1 − δ  [10]  ˜  O(  √  T)  Almost sure*  [11]  ˜  O(  √  T)  Convergence in probability*  This work  ˜  O(  √  T)  Almost sure  Requires non-standard assumptions;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' please refer to the  main text for details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='05537v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='OC]  13 Jan 2023  In this paper, we present an adaptive LQR controller with  ˜O(  √  T) regret almost surely, only assuming the availability  of a known stabilizing feedback gain, which is a common  assumption in the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' This is achieved by a “circuit-  breaking” mechanism motivated similarly as [11], which cir-  cumvents safety breach by supervising the norm of the state  and deploying the feedback gain when necessary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In contrast  to [11], however, by enforcing a properly chosen dwell time on  the fallback mode, the stability of the closed-loop system under  our proposed controller is unaffected by switching.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Another  insight underlying our analysis is that the above mentioned  circuit-breaking mechanism is triggered only finitely often.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  This fact implies that the conservativeness of the proposed  controller, which prevents the system from being destabilized  in the early stage and hence ensures the convergence of the  system parameter estimates, may have negligible effect on  the asymptotic performance of the system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Although similar  phenomena have also been observed in [11], [15], we derive  an upper bound on the time of the last trigger (Theorem 3,  item 7)), a property missing from pervious works that paves  the way to our almost sure regret guarantee.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Outline  The remainder of this manuscript is organized as follows:  Section II introduces the problem setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Section III describes  the proposed controller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Section IV states and proves the  theoretical properties of the closed-loop system under the pro-  posed controller, and establishes the main regret upper bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Section V validates the theoretical results using a numerical  example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Finally, Section VI summarizes the manuscript and  discusses directions for future work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Notations  The set of nonnegative integers is denoted by N, and the  set of positive integers is denoted by N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The n-dimensional  Euclidean space is denoted by Rn, and the n-dimensional  unit sphere is denoted by Sn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The n × n identity matrix is  denoted by In.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For a square matrix M, ρ(M) denotes the  spectral radius of M, and tr(M) denotes the trace of M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For  a real symmetric matrix M, M ≻ 0 denotes that M is positive  definite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For any matrix M, M † denotes the Moore-Penrose  inverse of M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For two vectors u, v ∈ Rn, ⟨u, v⟩ denotes  their inner product.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For a vector v, ∥v∥ denotes its 2-norm,  and ∥v∥P = ∥P 1/2v∥ for P ≻ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For a matrix M, ∥M∥  denotes its induced 2-norm, and ∥M∥F denotes its Frobenius  norm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For a random vector x, x ∼ N(µ, Σ) denotes x is  Gaussian distributed with mean µ and covariance Σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For a  random variable X, X ∼ χ2(n) denotes X has a chi-squared  distribution with n degrees of freedom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' P(·) denotes the  probability operator, and E[·] denotes the expectation operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  For non-negative quantities f, g, which can be deterministic  or random, we say f ≲ g to denote that f ≤ C1g+C2 for some  universal constants C1 > 0 and C2 > 0, and f ≳ g to denote  that g ≲ f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For a random function f(T) and a deterministic  function g(T), we say f(T) = O(g(T)) to denote that  lim supT →∞ f(T)/g(T) < ∞, and f(T) =  ˜O(g(T)) to  denote that f(T) = O(g(T)(log(T))α) for some α > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' PROBLEM FORMULATION  This paper considers a fully observed discrete-time linear  system with Gaussian process noise specified as follows:  xk+1 = Axk + Buk + wk,  k ∈ N∗,  x1 = 0,  (1)  where xk ∈ Rn is the state, uk ∈ Rm is the control input,  and wk  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼  N(0, W) is the process noise, where W ≻ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  It is assumed without loss of generality that W = In, but all  the conclusions apply to general positive definite W up to the  scaling of constants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It is also assumed that the system and  input matrices A, B are unknown to the controller, but (A, B)  is controllable, and that the system is open-loop stable, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=',  ρ(A) < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Consequently, there exists P0 ≻ 0 that satisfies the  discrete Lyapunov equation  A⊤P0A − P0 + Q = 0,  (2)  and there exists a scalar 0 < ρ0 < 1 such that  A⊤P0A ≺ ρ0P0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (3)  Remark 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It has been commonly assumed in the liter-  ature [9], [11] that (A, B) being stabilizable by a known  feedback gain K0, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', ρ(A + BK0) < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In such case, the  system can be rewritten as  xk+1 = A′xk + Bu′  k + wk,  (4)  where A′ = A + BK0, u′  k = uk − K0xk, which reduces the  problem to the case of open-loop stable systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Therefore,  we may assume without loss of generality that the system is  open-loop stable, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', K0 = 0, for the simplicity of notations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The following average infinite-horizon quadratic cost is  considered:  J = lim sup  T →∞  1  T E  � T  �  k=1  x⊤  k Qxk + u⊤  k Ruk  �  ,  (5)  where Q ≻ 0, R ≻ 0 are fixed weight matrices specified by the  system operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It is well known that the optimal control law  is the linear feedback control law of the form u(x) = K∗x,  where the optimal feedback gain K∗ can be specified as:  K∗ = −  �  R + B⊤P ∗B  �−1 B⊤P ∗A,  (6)  and P ∗ is the unique positive definite solution to the discrete  algebraic Riccati equation  P ∗ = A⊤P ∗A − A⊤P ∗B  �  R + B⊤P ∗B  �−1 B⊤P ∗A + Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (7)  The corresponding optimal cost is  J∗ = tr  �  E  �  wkw⊤  k  �  P ∗�  = tr(WP ∗) = tr(P ∗).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (8)  The matrix P ∗ also satisfies the discrete Lyapunov equation  (A + BK∗)⊤P ∗(A + BK∗) − P ∗ + Q + K⊤RK = 0, (9)  which implies that there exists a scalar 0 < ρ∗ < 1 such that  (A + BK∗)⊤P ∗(A + BK∗) ≺ ρ∗P ∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (10)  Since A, B are unknown to the controller in the considered  setting, it is not possible to directly compute the optimal  control law from (6) and (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Instead, the controller learns the  optimal control law online, whose performance is measured  via the regret defined as follows:  R(T) =  T  �  k=1  (x⊤  k Qxk + u⊤  k Ruk) − TJ∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (11)  The goal of the controller is to minimize the asymptotic growth  of R(T).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' CONTROLLER DESIGN  The logic of the proposed controller is presented in Algo-  rithm 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It can also be illustrated by the block diagram in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The remainder of this section would be devoted to  explaining the components of the controller:  Algorithm 1 Proposed controller  1: ˆK0 ← 0  2: ξ ← 0  3: for k = 1, 2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' do  4:  Update parameter estimates ˆAk, ˆBk using (12)  5:  if ( ˆAk, ˆBk) is controllable then  6:  Update ˆKk from (6)-(7), replacing (A, B) with  ( ˆAk, ˆBk).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  7:  else  8:  ˆKk ← 0  9:  uce  k ← ˆKkxk  10:  if ξ = 0 then  11:  if ∥uce  k ∥ > Mk := log(k) then  12:  ξ ← tk := ⌊log(k)⌋  13:  ucb  k ← 0  14:  else  15:  ucb  k ← uce  k  16:  else  17:  ucb  k ← 0  18:  ξ ← ξ − 1  19:  upr  k ← k−1/4vk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' where vk ∼ N(0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Im)  20:  Apply uk ← ucb  k + upr  k  The proposed controller is a variant of the certainty equiv-  alent controller [16],' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' where the latter applies the input uce  k =  ˆKkxk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' where the feedback gain ˆKk is calculated from (6)-  (7) by treating the current estimates of the system parameters  ˆAk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' ˆBk as the true values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The differences of the proposed  controller compared to the standard certainty equivalent con-  troller is that i) it includes a “circuit-breaking” mechanism,  which replace uce  k  with zero in certain circumstances;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' ii) it  superposes the control input at each step with a probing noise  upr  k .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The circuit-breaking mechanism replaces uce  k  with zero  for the subsequent tk steps when the norm of the certainty  equivalent control input ∥uce  k ∥ exceeds a threshold Mk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The  intuition behind this design is that a large certainty equivalent  control input is indicative of having applied a destabilizing  feedback gain recently, and circuit-breaking may prevent the  state from exploding by leveraging the innate stability of the  system, and hence help with the convergence of the parameter  Circuit-  breaking  logic  ξ > 0  0  ˆK  uce  ucb  +  Plant  (eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' (1))  Estimator  (eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' (7))  ξ  w  upr  u  x  ξ = 0  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 1: Block diagram of the closed-loop system under the  proposed controller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The control input is the superposition of  a deterministic input ucb and a random probing input upr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The  deterministic part ucb is normally the same as the certainty  equivalent input uce, but takes the value zero when circuit-  breaking is triggered, where ξ is a counter for circuit-breaking.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The certainty equivalent gain is updated using the parameter  estimator in the meantime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  estimator and the asymptotic performance of the controller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The threshold Mk is increased with the time index k, so  that the “false alarm rate” of circuit-breaking, caused by the  occasional occurrence of large noise vectors, decays to zero.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The dwell time tk is also increased with time, in order to  circumvent the potential oscillation of the system caused by  the frequent switching between ˆK and 0 (c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' [17]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Both Mk  and tk are chosen to grow logarithmically with k, which would  support our technical guarantees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Similarly to [9], [11], a probing noise upr  k is superposed to  the control input at each step to provide sufficient excitation  to the system, which is required for the estimation of system  parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Specifically, the probing noise is chosen to be  upr  k  = k−1/4vk, where vk  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼  N(0, Im), which would  correspond to the optimal rate of regret.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The estimates of the system parameters ˆAk, ˆBk are up-  dated using an ordinary least squares estimator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Denote Θ =  [A  B], ˆΘk  = [ ˆAk  ˆBk], and zk  = [x⊤  k  u⊤  k ]⊤, then  according to xk+1 = Θzk, the ordinary least squares estimator  can be specified as  ˆΘk =  �k−1  �  t=1  xtz⊤  t  � �k−1  �  t=1  ztz⊤  t  �†  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (12)  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In the presented algorithm, the certainty equivalent  gain is updated at every step k (see line 6 of Algorithm 1), but  it may also be updated “logarithmically often” [11] (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', at  steps k = 2i, i ∈ N∗), which is more computationally efficient  in practice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It can be verified that all our theoretical results  also apply to the case of logarithmically often updates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' MAIN RESULTS  Underlying our analysis of the closed-loop system under the  proposed controller are two random times, defined below:  Tstab := inf  �  T  ���  �  Atk�⊤ P ∗Atk < ρP ∗,  �  A + B ˆKk  �⊤  P ∗ �  A + B ˆKk  �  < ρP ∗, ∀k ≥ T  �  ,  (13)  where ρ = (1 + ρ∗)/2, and tk is the dwell time defined in  line 12 of Algorithm 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' And  Tnocb := inf  �  T | ucb  k ≡ uce  k , ∀k ≥ T  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (14)  With the above two random times, the evolution of the system  can be divided into three stages:  1) From the beginning to Tstab, the adaptive controller grad-  ually refines its estimate of system parameters, and hence  improves the performance of the certainty equivalent  feedback gain, until the system becomes stabilized in the  sense that there is a common Lyapunov function between  the two modes under circuit-breaking as indicated in (13).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) From Tstab to Tnocb, the closed-loop system is stable as is  ensured by the aforementioned common Lyapunov func-  tion, and under mild regularity conditions on the noise,  an upper bound on the magnitude certainty equivalent  control input ∥uce  k ∥ eventually drops below the circuit-  breaking threshold Mk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  3) From Tnocb on, circuit-breaking is not triggered any more,  and the system behaves similarly as the closed-loop  system under the optimal controller, with only small  perturbations on the feedback gain which stem from the  parameter estimation error and converge to zero.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  In the following theorem, we state several properties of the  closed-loop system, based on which the above two random  times are quantified:  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let n, m be the dimensions of the state and input  vectors respectively, and P0, ρ0, P ∗, ρ∗ be defined in (2), (3),  (7), (10) respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Then the following properties hold:  1) For 0 < δ ≤ 1/2, the event  Enoise(δ) :=  �  max{∥wk∥, ∥vk∥} ≤  2  √  n + 1  �  log(k/δ), ∀k ∈ N∗�  (15)  occurs with probability at least 1 − 2δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) For 0 < δ ≤ 1/(8n2), the event  Ecov(δ) :=  ������  k  �  i=1  (wiw⊤  i − In)  ����� ≤  7n  √  k log(8n2k/δ), ∀k ∈ N∗  �  (16)  occurs with probability at least 1 − δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  3) On the event Enoise(δ), it holds  ∥xk∥ ≤ Cx log(k/δ), ∀k ∈ N∗,  (17)  where  Cx = (∥B∥ + 1)(2√n + 1 + 1)∥P0∥∥P −1  0  ∥  1 − ρ1/2  0  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (18)  4) For 0 < δ ≤ 1/6, the event  Ecross(δ) :=  ������  k  �  i=1  w⊤  i P ∗(Axi + Bucb  i )  ����� ≤  Ccross  √  k(log(k/δ))2, ∀k ∈ N∗  �  (19)  occurs with probability at least 1 − 6δ, where  Ccross = 4  √  n + 1∥P ∗∥(∥A∥Cx + ∥B∥).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (20)  5) For δ satisfying  0 < δ < min  �  (800CV )−1, exp  �  24(m + n)1/3��  ,  (21)  the event  Eest(δ) :=  ����ˆΘk − Θ  ���  2  ≤ CΘk−1/2 log(k/δ),  ∀k ≥ k0  �  ,  (22)  occurs with probability at least 1 − 6δ, where  k0 = ⌈600(m + n) log(1/δ) + 5400⌉,  (23)  CV = Cx + 2  √  n + 1 + 1,  (24)  CΘ = (3200n/9)(5n/2 + 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (25)  6) On the event Eest(δ), it holds  Tstab ≲ (log(1/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (26)  7) On the event Enoise(δ) ∩ Eest(δ), for any α > 0, it holds  Tnocb ≲ (1/δ)α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (27)  Remark 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The conclusions of Theorem 3 can be explained  as follows:  Items 1) and 2) defines two high-probability events on the  regularity of noise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Item 3) bounds the state norm under regular  noise, based on which item 4) bounds the growth of a cross  term between noise and state that would be useful in regret  analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Item 5) bounds the parameter estimation error, based  on which item 6) bounds Tstab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Finally, item 7) states that  the circuit-breaking mechanism is triggered only finitely, and  bounds Tnocb, the time after which the circuit-breaking is not  triggered any more.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The following corollary characterizes the tail probabilities  of Tstab and Tnocb, which follows directly from items 6) and  7) of Theorem 3:  Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For Tstab defined in (13) and Tnocb defined  in (14), as T → ∞, it holds  1)  P(Tstab ≥ T) = O(exp(−c  √  T)),  (28)  where c > 0 is a system-dependent constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) For any α > 0,  P(Tnocb ≥ T) = O(T −α).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (29)  Building upon the properties stated in Theorem 3, a high-  probability bound on the regret under the proposed controller  can be ensured:  Theorem 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Given a failure probability δ, there exists a  constant T0 ≲ (1/δ)1/4, such that for any fixed T > T0,  it holds with probability at least 1 − δ that the regret defined  in (11) satisfies  R(T) ≲ (1/δ)1/4 +  √  T(log(T/δ))3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (30)  As corollaries of Theorem 6, one can obtain a bound on the  tail probability of R(T) (Theorem 7), and the main conclusion  of this work, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', an almost sure bound on R(T) (Theorem 8):  Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For sufficiently large T, it holds  P  �  R(T) ≥ CR  √  T(log(T))3�  ≤ 1  T 2 ,  (31)  where CR is a system-dependent constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The conclusion follows from invoking Theorem 6 with  δ = 1/T 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Theorem 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It holds almost surely that  R(T) = ˜O  �√  T  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (32)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' By Theorem 7, we have  ∞  �  T =1  P  �  R(T) ≥ CR  √  T(log(T))3�  < +∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (33)  By Borel-Cantelli lemma, it holds almost surely that the event  �  R(T) ≥ CR  √  T(log(T))3�  (34)  occurs finitely often, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=',  R(T) = ˜O  �√  T  �  ,  a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (35)  The remainder of this section is dedicated to proving  Theorems 3 and 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 1)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Since wk ∼ N(0, In), it holds ∥wk∥ ∼ χ2(n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Apply-  ing the Chernoff bound, for any a > 0, and any 0 < t < 1/2,  it holds  P(X ≥ a) ≤ E  �  etX/eta�  = (1 − 2t)−n/2 exp(−ta).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (36)  Choosing t = 1/4, we have  P(∥wk∥ ≥ a) ≤ 2n/2 exp(−a2/4)  (37)  for any k ∈ N∗ and a > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Invoking (37) with ak =  2(log(ck2/δ))1/2, where c = 2n/2π2/6, we have  ∞  �  k=1  P(∥wk∥ ≥ ak) ≤  ∞  �  k=1  2n/2c−1δ/k2 = δ,  (38)  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', it holds with probability at least 1 − δ that  ∥wk∥ ≤ 2(log(ck2/δ))1/2 ≤ 2  √  n + 1  �  log(k/δ), ∀k ∈ N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (39)  Similarly, it also holds with probability at least 1 − δ that  ∥vk∥ ≤ 2  √  n + 1  �  log(k/δ), ∀k ∈ N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (40)  Combining (39) and (40) leads to the conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 2)  We start with a concentration bound on the sum of product  of Gaussian random variables:  Lemma 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let Xi  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼  N(0, 1), Yi  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼  N(0, 1), and  {Xi}, {Yi} be mutually independent, then  1) With probability at least 1 − 4δ,  �����  k  �  i=1  X2  i − k  ����� ≤ 7  √  k log(k/δ), ∀k ∈ N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (41)  2) With probability at least 1 − 8δ,  �����  k  �  i=1  XiYi  ����� ≤ 5  √  k log(k/δ), ∀k ∈ N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (42)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Since �k  i=1 X2  i ∼ χ2(k), according to [18, Lemma 1],  for any a > 0 and any k ∈ N∗, it holds  P  ������  k  �  i=1  X2  i − k  ����� ≥ 2√na + 2a  �  ≤ 2 exp(−a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (43)  Fix k and choose a = log(k2/δ), and it follows that with  probability at least 1 − 2δ/k2,  �����  k  �  i=1  X2  i − k  ����� ≤ 2  �  k log(k2/δ) + 2 log(k2/δ)  ≤ 7  √  k log(k/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (44)  Taking the union bound over k ∈ N∗, one can show that (41)  holds with probability at least 1 − 2δ �∞  k=1(1/k2) > 1 − 4δ,  and hence claim 1) is proved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Since XiYi = (Xi+Yi)2/4+(Xi−Yi)2/4, and Xi+Yi  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼  N(0, 2), Xi−Yi  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼ N(0, 2), claim 2) follows from applying  claim 1) to {(Xi +Yi)/  √  2} and {(Xi −Yi)/  √  2} respectively  and taking the union bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Theorem 3, item 2) follows from the above lemma:  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Applying Lemma 9, item 1) to the diagonal elements,  and Lemma 9, item 2) to the off-diagonal elements of  �k  i=1(wiw⊤  i − I), and taking the union bound, one can show  that with probability at least 1 − 8n2δ,  k  �  i=1  (wiw⊤  i − In) ≤ 7  √  k log(k/δ),  (45)  where the inequality holds component-wise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Hence, with prob-  ability at least 1 − 8n2δ,  �����  k  �  i=1  (wiw⊤  i − In)  �����  2  ≤  �����  k  �  i=1  (wiw⊤  i − In)  �����  2  F  ≤ n2(7  √  k log(k/δ)),  (46)  and scaling the failure probability leads to the conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 3)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Notice  xk = Ak−2d1 + Ak−3d2 + · · · + dk−1,  (47)  where dk = B(ucb  k + upr  k ) + wk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' On Enoise(δ), it holds  ∥dk∥ ≤ ∥B∥ log(k) + 2(∥B∥ + 1)  √  n + 1  �  log(k/δ)  ≤ (∥B∥ + 1)(2  √  n + 1 + 1) log(k/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (48)  Furthermore, from (2) and (47), it holds  ∥xk∥P ≤ ρ(k−2)/2  0  ∥d1∥P + ρ(k−3)/2  0  ∥d2∥P + · · · + ∥dk−1∥P  ≤  1  1 − ρ1/2  0  ∥dk∥P ,  (49)  from which the conclusion follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 4)  This result is a corollary of a time-uniform version of  Azuma-Hoeffding inequality [19], stated below:  Lemma 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let {φk}k≥1 be a martingale difference sequence  adapted to the filtration {Fk} satisfying |φk| ≤ dk a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', then  with probability at least 1 − 4δ, it holds  �����  k  �  i=1  φi  ����� ≤ 2  �  �  �  �  k  �  i=1  d2  i log(k/δ), ∀k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (50)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' By Azuma-Hoeffding inequality [19], for a fixed k, it  holds with probability at least 1 − 2δ/k2 that  �����  k  �  i=1  φi  ����� ≤  �  �  �  �2  k  �  i=1  d2  i log(k2/δ) ≤ 2  �  �  �  �  k  �  i=1  d2  i log(k/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (51)  Taking the union bound over k ∈ N∗, one can prove that (50)  holds with probability at least 1 − 2δ �∞  k=1(1/k2) > 1 −  4δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Theorem 3, item 4) follows from the above lemma:  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' According to Theorem 3, item 1), we only need to  prove  P(Ecross(δ) | Enoise(δ)) ≥ 1 − 4δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (52)  Therefore, we condition the remainder of the proof upon the  event Enoise(δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let Fk be the σ-algebra generated by v1, w1,  v2, w2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' , vk−1, wk−1, vk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Since xk ∈ Fk−1, ucb  k ∈ Fk−1,  E[wk | Fk−1] = 0 due to symmetry, it holds  E  �  w⊤  k P ∗ �  Axk + Bucb  k  � ��Fk  �  =E [wk | Fk−1]⊤ P ∗ �  Axk + Bucb  k  �  = 0,  (53)  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', {w⊤  k P ∗(Axk+Bucb  k )} is a martingale difference sequence  adapted to the filtration {Fk}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Furthermore, by Theorem 3,  item 3, we have  ��w⊤  k P ∗ �  Axk + Bucb  k  ���  ≤∥wk∥∥P ∗∥  �  ∥A∥∥xk∥ + ∥B∥  ��ucb  k  ���  ≤1  2Ccross log(k/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (54)  Hence, the conclusion follows from applying Lemma 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 5)  This subsection is devoted to deriving the time-uniform  upper bound on estimation error stated in Theorem 3, item 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Throughout this subsection, we denote Θ = [A  B], ˆΘk =  [ ˆAk  ˆBk], zk = [x⊤  k  u⊤  k ]⊤, and Vk = �k−1  i=1 ziz⊤  i .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The proof can be split into three parts: firstly, we character-  ize the estimation error ∥ˆΘk − Θ∥ in terms of the maximum  and minimum eigenvalues of the regressor covariance matrix  Vk, using a result in martingale least squares [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Secondly,  an upper bound on the ∥Vk∥, which is a consequence of the  non-explosiveness of states, can be derived as an corollary  of Theorem 3, item 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Finally, an upper bound on ∥V −1  k  ∥,  or equivalently a lower bound on the minimum eigenvalue  of Vk, which is a consequence of sufficient excitation of the  system, can be proved using an anti-concentration bound on  block martingale small-ball (BMSB) processes [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The three  parts would be discussed respectively below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  1) Upper bound on least squares error, in terms of Vk:  Lemma 11 ( [5, Corollary 1 of Theorem 3]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let  Sk =  k  �  i=1  ηimi−1, Uk =  k  �  i=1  mi−1m⊤  i−1,  (55)  where {Fk}k∈N∗ is a filtration, {ηk}k∈N∗ is a random scalar  sequence with ηk | Fk being conditionally σ2-sub-Gaussian,  and {mk}k∈N∗ is a random vector sequence with mk ∈ Fk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Then with probability at least 1 − δ,  ∥Sk∥(U0+Uk)−1 ≤ 2σ2·  log  �  det(U0)−1/2 det(U0 + Uk)1/2/δ  �  ,  ∀k ∈ N∗, (56)  where U0 ≻ 0 is an arbitrarily chosen constant positive semi-  definite matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Proposition 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' With probability at least 1 − δ,  ���ˆΘk − Θ  ���  2  ≤ 2n  ��V −1  k  ��  �  log  �n  δ  �  + n  2 log(1 + ∥Vk∥)  �  ,  ∀k ≥ m + n + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (57)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let Fk be the σ-algebra generated by v1, w1, v2, w2,  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' , vk−1, wk−1, vk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' From xk+1 = Θzk + wk, we have  ˆΘk − Θ =  �k−1  �  i=1  wiz⊤  i  � �k−1  �  i=1  ziz⊤  i  �†  ,  (58)  where wk|Fk ∼ N(0, In), zk ∈ Fk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' With Vk = �k−1  i=1 ziz⊤  i ,  we have Vi ≻ 0 a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' for k ≥ m + n + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Now we can apply  Lemma 11 to each row of ˆΘk − Θ: for each of j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' , n,  let Sj,k = �k−1  i=1 (e⊤  j wi)zi, where ej is the j-th standard unit  vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' By invoking Lemma 11 with Uk = Vk and U0 = Im+n,  we have: with probability at least 1 − δ,  ���e⊤  j (ˆΘk − Θ)  ���  2  =  ��V −1  k  Sj,k  �� ≤  ��V −1  k  �� ∥Sj,k∥(I+Vk)−1  ≤ 2  ��V −1  k  �� log  �  det(I + Vk)1/2/δ  �  ≤ 2  ��V −1  k  ��  �  log  �1  δ  �  + n  2 log(1 + ∥Vk∥)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (59)  Taking the union bound over j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' , n, we have: with  probability at least 1 − nδ,  ���ˆΘk − Θ  ���  2  ≤  ���ˆΘk − Θ  ���  2  F  ≤  n  �  j=1  ���e⊤  j (ˆΘk − Θ)  ���  2  ≤2n  ��V −1  k  ��  �  log  �1  δ  �  + n  2 log(1 + ∥Vk∥)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (60)  Scaling the failure probability results in the conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) Upper bound on ∥Vk∥:  Proposition 13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' On the event Enoise(δ) defined in (15), it holds  ∥Vk∥ ≤ CV k(log(k/δ))2,  (61)  where CV is defined in (24).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' On Enoise(δ), we have  ∥uk∥ ≤ log(k) + 2  √  n + 1  �  log(k/δ),  (62)  and by Theorem 3, item 3), we have  ∥xk∥ ≤ Cx log(k/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (63)  Hence,  ∥zk∥ ≤ ∥xk∥ + ∥uk∥ ≤  �  CV log(k/δ),  (64)  which implies  ∥Vk∥ ≤  k−1  �  i=1  ∥zk∥2 ≤ CV k(log(k/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (65)  3) Upper bound on ∥V −1  k  ∥: We shall borrow the techniques  of analyzing BMSB processes from Simchowitz et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' [20] to  bound ∥V −1  k  ∥.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The BMSB process is defined as follows:  Definition 14 ( [20, Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='1]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Suppose that {φk}k∈N∗ is  a real-valued stochastic process adapted to the filtration {Fk}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  We say the process {φk} satisfies the (l, ν, p) block martingale  small-ball (BMSB) condition if:  1  l  l  �  i=1  P (|φk+i| ≥ ν | Ft) ≥ p, ∀k ∈ N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (66)  The following lemma verifies that {zk}, projected along an  arbitrary direction, is BMSB:  Lemma 15.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For any µ ∈ Sm+n, the process {⟨zi, µ⟩}k−1  i=1  satisfies the (1, k−1/4, 3/10) BMSB condition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let Fk be the σ-algebra generated by v1, w1, v2, w2,  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' , vk−1, wk−1, vk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Since  zi =  �xi  ui  �  =  �  xi  ucb  i + upr  i  �  ,  (67)  and xi+1 = Aixt + Bupr  i  + wi, where Ai takes value from  {A, A + B ˆKi} and belongs to Fi, we have  |⟨zi+1, µ⟩| = |⟨xi+1, µ1⟩ + ⟨ucb  i+1, µ2⟩ + ⟨upr  i+1, µ2⟩|  ≥ |⟨Aixi + Bupr  i + wi, µ1⟩ + ⟨upr  i+1, µ2⟩|  =  ����  � �Aixi + Bupr  i + wi  upr  i+1  �  , µ  ����� ,  (68)  where µ1 = [In  0]µ, µ2 = [0  Im]µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Therefore, we only  need to verify  P  �����  � �Aixi + Bupr  i + wi  upr  i+1  �  , µ  ����� ≥ k−1/4���Fi  �  ≥ 3  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' (69)  Since Aixi ∈ Fi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' and upr  i  | Fi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' wi | Fi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' upr  i+1 | Fi are all  Gaussian,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  � �Aixi + Bupr  i + wi  upr  i+1  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' µ  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (70)  as an affine function of the above terms,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' is also Fi-  conditionally Gaussian,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' whose mean and variance are:  E  �� �Aixi + Bupr  i + wi  upr  i+1  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' µ  ����� Fi  �  = ⟨Aixi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' µ1⟩,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  E  ��� �Aixi + Bupr  i + wi  upr  i+1  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' µ  �  − ⟨Aixi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' µ1⟩  �2����� Fi  �  = E  �� �Bupr  i + wi  upr  i+1  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' µ  �2���� Fi  �  = µT  �  i−1/2BB⊤ + I  0  0  (i + 1)−1/2  �  µ  ≥ µT  �I  0  0  k−1/2  �  µ ≥ k−1/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (71)  The conclusion (69) then follows from the fact that for any  X ∼ N(µ, σ2), it holds P(|X| ≥ σ) ≥ P(|X − µ| ≥ σ) ≥  3/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  An upper bound on ∥V −1  k  ∥ can be obtained by applying an  anti-concentration property of BMSB, along with a covering  argument in [20]:  Lemma 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For any fixed k ≥ 2 and 0 < δk ≤ 1/2, it holds  P  ���V −1  k  �� ≥ 1600  9  k−1/2  �  ≤  δk + e−  9  800 k+(m+n) log(800CV k1/2(log(k/δk))2),  (72)  where CV is defined in Theorem 3, item 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Firstly, for any fixed µ ∈ Sm+n, applying [20, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='5] to the process {⟨zi, µ⟩}k−1  i=1 , which is (1, k−1/4, 3/10)-  BMSB by Lemma 15, we have  P  �k−1  �  i=1  ⟨zi, µ⟩2 ≤ k−1/2(3/10)2  8  k  �  ≤ e− (3/10)2k  8  ,  (73)  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=',  P  �  µ⊤Vkµ ≤  9  800k1/2  �  ≤ e−  9  800 k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (74)  Next, we shall choose multiple µ’s and using a covering  argument to lower bound the minimum eigenvalue of Vk, and  hence to upper bound ∥V −1  k  ∥: let Γ = CV k(log(k/δk))2Im+n,  and Γ = (9/800)k1/2Im+n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let T be a minimal 1/4-net of  SΓ in the norm ∥ · ∥Γ, then by [20, Lemma D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='1], we have  log |T | ≤ (m + n) log(9) + log det(ΓΓ−1)  ≤ (m + n) log(800CV k1/2(log(k/δk))2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (75)  According to (74) and (75), we have  P  �  µ⊤Vkµ ≤  9  800k1/2, ∀µ ∈ T  �  ≤ |T |e−  9  800 k  ≤ e−  9  800 k+(m+n) log(800CV k1/2(log(k/δk))2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (76)  On the other hand, according to Proposition 13 and Theorem 3,  item 1), we have  P  �  ∥Vk∥ ≤ CV k(log(k/δk))2�  ≤ δk,  (77)  From (76), (77) and [20, Lemma D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='1], it follows that  P (Vk ≻ Γ/2) is no greater than the RHS of (72), which is  equivalent to the conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The next proposition converts Lemma 16 into a time-  uniform bound:  Proposition 17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For δ satisfying (21) and k0 defined in (23),  it holds  P  ���V −1  k  �� ≤ 1600  9  k−1/2, ∀k ≥ k0  �  ≤ 3δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (78)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For k ≥ k0, with δk = δ/k2, it holds  k ≥ (1300(m + n))4/3 ,  (79)  and hence,  (m + n) log(800CV k1/2(log(k/δk))2)  ≤(m + n)  �  3 log(1/δ) + 13  2 log(k)  �  ≤ 1  200k + 13  2 (m + n)k1/4 ≤  1  100k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (80)  Substituting (80) into (72), we have  P  ���V −1  k  �� ≥ 1600  9  k−1/2  �  ≤ δ  k2 + e−  1  800 k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (81)  Taking the union bound over k = k0, k0 + 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', we have  P  ���V −1  k  �� ≥ 1600  9  k−1/2, ∀k ≥ k0  �  ≤π2  6 δ + 801e−  1  800 k0 ≤ 3δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (82)  Theorem 3, item 5) follows from Propositions 12, 13 and  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 6)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let  T1 = inf  �  T  ���  �  Atk�⊤ P ∗Atk < ρP ∗, ∀k ≥ T  �  ,  (83)  T2 = inf  �  T  ����  �  A + B ˆKk  �⊤  P ∗ �  A + B ˆKk  �  < ρP ∗,  ∀k ≥ T  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (84)  We shall bound T1 and T2 respectively:  1) From the assumption ρ(A) < 1, it holds  lim  k→∞  �  Ak�⊤ PAk = 0,  (85)  which, together with tk = ⌊log(k)⌋, implies T1 is a finite  constant independent of δ, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', T1 ≲ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) Since (A + BK)⊤P ∗(A + BK) is a continuous function  of K, from (10), there exists a system-dependent con-  stant ϵK, such that (A + BK)⊤P ∗(A + BK) < ρP ∗  whenever ∥K − K∗∥ < ϵK.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' On the other hand, since  ˆKk is a continuous function of ˆΘk [9, Proposition 6],  there exists a system-dependent constant ϵΘ, such that  ∥ ˆK − K∗∥ < ϵK as long as ∥ˆΘk − Θ∥ < ϵΘ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It follows  from Theorem 3, item 5) that ∥ˆΘk − Θ∥ < ϵΘ whenever  k ≥ (9C2  Θ/ϵ2  Θ)(log(1/δ))2, and hence T2 ≲ (log(1/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  In summary, it holds Tstab = max{T1, T2} ≲ (log(1/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 3, item 7)  This subsection is dedicated to bounding the time after  which the circuit-breaking is not triggered any more.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The  outline of the proof is stated as follows: firstly, we define  a subsequence notation to deal with the dwell time tk of  circuit breaking.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Secondly, an upper bound on the state and  the certainty equivalent input after Tstab is derived, which is  shown to be asymptotically smaller than the circuit-breaking  threshold Mk = log(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Based on the above upper bound on  the certainty equivalent input, we can finally bound Tnocb, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=',  the time it takes for the certainty equivalent input to stay below  the threshold Mk, which leads to the desired conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  1) A subsequence notation: Consider the subsequence of  states and inputs, where steps within the circuit-breaking  period are skipped, defined below:  i(1) = 1, i(k + 1) =  �  i(k) + 1  ucb  i(k) ̸= 0  i(k) + ti(k)  ucb  i(k) = 0 ,  (86)  ˜xk = xi(k), ˜uce  k = uce  i(k), ˜ucb  k = ucb  i(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (87)  Consider Tstab defined in (13).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' We can define ˜Tstab as the  first index in the above subsequence for which the stabilization  condition is satisfied, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=',  ˜Tstab = inf{T | i(T) ≥ Tstab}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (88)  2) Upper bound on state and certainty equivalent input  after Tstab:  Proposition 18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' On the event Enoise(δ) ∩ Eest(δ), it holds  ��˜x ˜Tstab+k  �� ≲ ρk/2 log(1/δ) +  �  log(k/δ),  (89)  ���˜uce  ˜Tstab+k  ��� ≲ ρk/2 log(1/δ) +  �  log(k/δ),  (90)  where ρ = (1 + ρ∗)/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' We can expand ˜x ˜Tstab+k as:  ˜x ˜Tstab+k = ˜A ˜Tstab+k−1 ˜A ˜Tstab+k−2 · · · ˜A ˜Tstab ˜x ˜Tstab+  ˜A ˜Tstab+k−1 ˜A ˜Tstab+k−2 · · · ˜A ˜Tstab+1 ˜w ˜Tstab+  · · +  ˜w ˜Tstab+k−1,  (91)  where:  ˜Aj ∈ {A + B ˆKi(j), Ati(j)}, and must satisfy ˜A⊤  j P ˜Aj <  ρP for j ≥ ˜Tstab, by definition of ˜Tstab in (13);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ˜wj ∈ {wi(j), �ti(j)−1  τ=0  Aτwi(j−1)+τ}, and on the event  Enoise(δ), it must satisfy ∥ ˜wj∥  ≲  A  �  log(j/δ)  ≲  �  log(j/δ) for any j, where A = �∞  τ=0 ∥Aτ∥.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Combining the above two items, we have  ��˜x ˜Tstab+k  �� ≲ ρk/2 ��˜x ˜Tstab  �� +  �  log  �  i  �  ˜Tstab + k  �  /δ  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' (92)  We shall next bound  ��˜x ˜Tstab  �� and i( ˜Tstab + k) respectively:  1) According to the definition of ˜Tstab and i(·) in (86)  and (88), we have  i  �  ˜Tstab  �  ≤ Tstab + log(Tstab).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (93)  On Eest(δ), according to Theorem 3, item 6, we have  Tstab ≲ (log(1/δ))2, and hence  i  �  ˜Tstab  �  ≲ (log(1/δ))2 + log((log(1/δ))2)  ≲ (log(1/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (94)  Furthermore, according to Theorem 3, item 3, on  Enoise(δ), we have ∥xk∥ ≲ log(k/δ) for any k, and hence  ��˜x ˜Tstab  �� =  ���xi( ˜Tstab)  ��� ≲ log  �(log(1/δ))2  δ  �  = log(1/δ) + log((log(1/δ))2) ≲ log(1/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (95)  2) By definition of i(·) in (86), we have  i  �  ˜Tstab + k + 1  �  ≤ ˜Tstab +k+log  �  ˜Tstab + k  �  , ∀k ∈ N∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (96)  Applying induction to (93) and (96), we can obtain  i  �  ˜Tstab + k  �  ≲ k log(Tstabk) + Tstab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (97)  Substituting Tstab ≲ (log(k/δ))2, which holds on Eest(δ)  according to Theorem 3, item 6), into (97), we have  i  �  ˜Tstab + k  �  ≲ k(log(k/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (98)  Hence, inequality (89) follows from substituting (95) and  (98) into (92).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Moreover, since  ��� ˆKi( ˜Tstab+k)  ��� is uniformly  bounded by definition of Tstab in (13), we have  ���˜uce  ˜Tstab+k  ��� ≤  ��� ˆKi( ˜Tstab+k)  ���  ��˜x ˜Tstab+k  �� ≲  ��˜x ˜Tstab+k  �� ,  (99)  which implies (90).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  3) Upper bound on Tnocb: Now we are ready to prove  Theorem 3, item 7):  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' For any ϵ > 0, according to (98), we have i( ˜Tstab+k) ≲  (1/δ)α+ϵ as long as k ≲ (1/δ)α−ϵ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Hence, we only need to  prove  ucb  k ≡ uce  k ,  ∀k ≥ i  �  ˜Tstab + k0  �  ,  (100)  for some k0 ≲ (1/δ)α−ϵ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Notice that (100) is equivalent to  ˜ucb  ˜Tstab+k ≡ ˜uce  ˜Tstab+k,  ∀k ≥ k0,  (101)  which is then equivalent to  ���˜uce  ˜Tstab+k  ��� ≤ Mk = log(k),  ∀k ≥ k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (102)  According to Proposition 18, we only need to verify  ρk/2 log(1/δ) +  �  log(k/δ) ≲ log(k),  (103)  whenever k ≳ (1/δ)α−ϵ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In such case, we have  ρk/2 log(1/δ) +  �  log(k/δ)  ≲ log(1/δ) +  �  log(k) + log(1/δ)  ≲ log(k) +  �  log(k) ≲ log(k),  (104)  from which the conclusion follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Proof of Theorem 6  In this subsection, we first decompose the regret of the  proposed controller into multiple terms, then derive upper  bounds on the terms respectively to obtain the high-probability  regret bound stated in Theorem 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  1) Regret decomposition:  We first state a supporting  lemma:  Lemma 19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Let K∗, P ∗ be defined in (6), (7) respectively,  and K = K∗ + ∆K, then  Q + K⊤RK + (A + BK)⊤ P ∗ (A + BK) − P ∗  =∆K⊤(R + B⊤P ∗B)∆K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (105)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Substituting the Lyapunov equation (9) into the LHS  of (105), we have  Q + K⊤RK + (A + BK)⊤P ∗(A + BK) − P ∗  =K⊤RK − (K∗)⊤ RK∗ + (A + BK)⊤P ∗(A + BK)−  (A + BK∗)⊤ P ∗ (A + BK∗)  =∆K⊤ �  R + B⊤P ∗B  �  ∆K + G + G⊤,  (106)  where  G = ∆K⊤ �  (R + B⊤P ∗B)K∗ + B⊤P ∗A  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (107)  By definition of K∗ in (6), we have G = 0, and hence the  conclusion holds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Now we are ready to state the decomposition of regret:  Proposition 20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The regret of the proposed controller defined  in (11) can be decomposed as  R(T) =  7  �  i=1  Ri(T),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (108)  with the terms Ri(T) defined as:  R1(T) =  T  �  k=1  x⊤  k (Kk − K∗)⊤(R + BT P ∗B)(Kk − K∗)xk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (109)  R2(T) = 2  T  �  k=1  (upr  k )⊤ B⊤P ∗(A + BKk)xk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (110)  R3(T) = 2  T  �  k=1  w⊤  k P ∗(A + BKk)xk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (111)  R4(T) =  T  �  k=1  (s⊤  k P ∗sk − w⊤  k P ∗wk),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (112)  R5(T) =  T  �  k=1  w⊤  k P ∗wk − TJ∗,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (113)  R6(T) = x⊤  1 P ∗x1 − x⊤  T +1P ∗xT +1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (114)  R7(T) =  T  �  k=1  2 (upr  k )⊤ Rucb  k + (upr  k )⊤ Rupr  k ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (115)  where Kk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' sk are defined as:  Kk =  � ˆKk  ucb  k = uce  k  0  otherwise ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' sk = Bupr  k + wk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (116)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' From uk = ucb  k + upr  k = Kkxk + upr  k , it holds  R(T) =  T  �  k=1  �  x⊤  k Qxk + u⊤  k Ruk  �  − TJ∗  =  T  �  k=1  �  x⊤  k  �  Q + K⊤  k RKk  �  xk + 2 (upr  k )⊤ Rucb  k +  (upr  k )⊤ Rupr  k  �  − TJ∗  =  T  �  k=1  �  x⊤  k  �  Q + K⊤  k RKk  �  xk + x⊤  k+1P ∗xk+1−  x⊤  k P ∗xk  �  − TJ∗ + R6(T) + R7(T).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (117)  We can further expand the summands in the RHS of the above  inequality: from xk+1 = (A + BKk)xk + sk, we have  x⊤  k  �  Q + K⊤  k RKk  �  xk + x⊤  k+1P ∗xk+1 − x⊤  k P ∗xk  =x⊤  k  �  Q + K⊤  k RKk + (A + BKk)⊤P ∗(A + BKk) − P ∗�  xk  + 2s⊤  k P ∗(A + BKk)xk + s⊤  k P ∗sk  =x⊤  k (Kk − K∗)⊤(R + B⊤P ∗B)(Kk − K∗)xk+  2s⊤  k P ∗(A + BKk)xk + s⊤  k P ∗sk,  (118)  where the last equality follows from Lemma 19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' It follows  from simple algebra that  T  �  k=1  �  x⊤  k  �  Q + K⊤  k RKk  �  xk + x⊤  k+1P ∗xk+1 − x⊤  k P ∗xk  �  − TJ∗  =  5  �  i=1  Ri(T),  (119)  and hence the conclusion follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) Upper bound on regret terms: Next we shall bound the  terms Ri(T) (i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' , 8) respectively:  Proposition 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The regret terms defined in (109)-(115) can  be bounded as follows:  1) On the event Enoise(δ) ∩ Eest(δ), for T > Tnocb, it holds  R1(T) ≲ (1/δ)1/4(log(1/δ))4+  √  T(log(T/δ))3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' (120)  2) On the event Enoise(δ), it holds  |R2(T)| ≲  √  T(log(T/δ))3/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (121)  3) On the event Ecross(δ), it holds  |R3(T)| ≲  √  T(log(T/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (122)  4) On the event Enoise(δ), it holds  |R4(T)| ≤  √  T log(T/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (123)  5) On the event Ecov(δ), it holds  |R5(T)| ≲  �  T log(1/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (124)  6) On the event Enoise(δ), it holds  |R6(T)| ≲ (log(T/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (125)  7) On the event Enoise(δ), it holds  |R7(T)| ≲  √  T log(T/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (126)  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  1) Let  r1k = x⊤  k (Kk − K∗)⊤ �  R + B⊤P ∗B  �  (Kk − K∗)xk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (127)  We shall next bound �Tnocb  k=1 r1k and �T  k=Tnocb+1 r1k re-  spectively:  a) For k ≤ Tnocb, we have ∥xk∥ ≲ log(k/δ) by The-  orem 3, item 3), and ∥Kkxk∥ = ∥ucb  k ∥ ≤ log(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Therefore, it holds  r1k ≲ (log(k/δ))2,  (128)  and hence,  Tnocb  �  k=1  r1k ≲ Tnocb(log(Tnocb/δ))2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (129)  Invoking Theorem 3, item 7 with α = 1/4, we get  Tnocb  �  k=1  r1k ≲ (1/δ)1/4(log(1/δ))4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (130)  b) For k ≤ Tnocb, by definition of Tnocb, we have Kk =  ˆKk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Hence, by definition of Eest and the fact that ˆKk  is a continuous function of ˆΘk [9, Proposition 6], we  have  ∥Kk − K∗∥ =  ��� ˆKk − K∗���  ≲  ���ˆΘk − Θ  ��� ≲ k−1/4(log(k/δ))1/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (131)  Furthermore, by Theorem 3, item 3, we have ∥xk∥ ≲  log(k/δ), and hence,  r1k ≲ ∥Kk−K∗∥2∥xk∥2 ≲ k−1/2(log(k/δ))3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' (132)  Therefore,  T  �  k=Tnocb+1  r1k ≲  √  T(log(T/δ))3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (133)  Summing up (130) and (133) leads to (120).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2) Let  r2k = (upr  k )⊤ B⊤P ∗(A + BKk)xk,  (134)  whose factors can be bounded as follows:  ∥upr  k ∥ = k1/2∥vk∥ ≲ k−1/2(log(k/δ))1/2 by defini-  tion of Enoise;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∥xk∥ ≲ log(k/δ) by Theorem 3, item 3);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∥Kkxk∥ =  ��ucb  k  �� ≤ Mk = log(k) according to the  proposed controller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Hence,  |r2k| ≲ k−1/2(log(k/δ))3/2,  (135)  and summing up (135) from k = 1 to T leads to (121).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  3) The inequality (122) follows directly from the definition  of Ecross(δ) in (19).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  4) Let  r4k = s⊤  k P ∗sk − w⊤  k P ∗wk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (136)  From sk = wk + Bupr  k = wk + k−1/2Bvk, we have  r4k = 2k−1/2w⊤  k P ∗Bvk + k−1v⊤  k B⊤P ∗Bvk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (137)  Hence, by definition of Enoise(δ), we have  |r4k| ≲ k−1/2 log(k/δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  (138)  Summing up (138) from k = 1 to T leas to (123).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  5) Since J∗ = tr(P ∗) (see (8)), we have  |R5(T)| =  �����  T  �  k=1  tr(wkw⊤  k P) − T tr(P)  �����  =  �����tr  �� T  �  k=1  (wkw⊤  k − In)  �  P  ������  ≲  �����  T  �  k=1  (wkw⊤  k − In)  ����� ≲  �  T log(1/δ), (139)  where the last inequality follows from the definition of  Ecov(δ), which proves (124).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  6) The inequality (125) is a direct corollary of Theorem 3,  item 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  7) Let  r7k = 2 (upr  k )⊤ Rucb  k + (upr  k )⊤ Rupr  k ,  (140)  where upr  k and ucb  k satisfy:  ∥upr  k ∥ = k−1/2∥vk∥ ≲ k−1/2(log(k/δ))1/2 by defini-  tion of Enoise(δ);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' ��ucb  k  �� ≤ Mk = log(k) according to the proposed  controller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Hence,  |r7k| ≲ k−1/2 log(k/δ),  (141)  and summing up (141) from k = 1 to T leads to (126).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  Theorem 6 follows from combining Propositions 20 and 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' SIMULATION  In this section, the proposed controller is validated on  the Tennessee Eastman Process (TEP) [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' In particular, we  consider a simplified version of TEP similar to the one in [22],  with full state feedback.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The system is open-loop stable, and  has state dimension n = 8 and input dimension m = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The  process noise distribution is chosen to be wk  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  ∼  N(0, In).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The weight matrices of LQR are chosen to be Q = In and  R = Im.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' The plant under the proposed controller is simulated  for 10000 independent trials, each with T = 3 × 108 steps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  As mentioned in Remark 2, the certainty equivalent gain ˆKk  is updated only at steps k = 2i, i ∈ N∗ for the sake of fast  computation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  The evolution of regret against time is plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  For the ease of observation, we plot the relative average  regret R(T)/(TJ∗) against the total time step T, where J∗  is the optimal cost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 2 shows 5 among the 10000 trials,  from which one can observe a 1/  √  T convergence rate of the  relative average regret (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=', a 1 order-of-magnitude increase  in T corresponds to a 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='5 order-of-magnitude decrease in  R(T)/(TJ∗)), which matches the  √  T theoretical growth rate  of regret.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' To inspect the statistical properties of all the trials,  we sort them by the average regret at the last step, and plot  the worst, median and mean cases in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 2b.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' One can observe  that the average regret converge to zero even in the worst case,  which validates the almost-sure guarantee in Theorem 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  102  103  104  105  106  107  108 3 × 108  10−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='5  10−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='0  10−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='5  10−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='0  10−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='5  100.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='0  100.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='5  Total time step T  R(T)/(TJ∗)  (a) Five random sample paths  102  103  104  105  106  107  108 3 × 108  10−5  10−4  10−3  10−2  10−1  100  Total time step T  R(T)/(TJ∗)  Worst  Median  Best  (b) Worst, median and best cases among all sample paths  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 2: Double-log plot of average regret against time step  An insight to behold on the performance of the proposed  controller is that the circuit-breaking mechanism is triggered  only finitely, and the time of the last trigger Tnocb, as stated  in Corollary 5, has a super-polynomial tail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' This insight is  also empirically validated: among all the 10000 trials, circuit-  breaking is never triggered after step 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='4×106, and a histogram  of Tnocb is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 3, from which one can observe that  the empirical distribution of Tnocb has a fast decaying tail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content='  2  4  6  8  10  12  14  0  200  400  600  800  1000  1200  Tnocb(×105)  Frequency  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' 3: Histogram of Tnocb among all sample paths  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' CONCLUSION  In this paper, we propose an adaptive LQR controller that  can achieve ˜O(  √  T) regret almost surely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' A key underlying  the controller design is a circuit-breaking mechanism, which  ensures the convergence of the parameter estimate, but is  triggered only finitely often and hence has negligible effect  on the asymptotic performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
+page_content=' A future direction would be  extending such circuit-breaking mechanism to the partially  observed LQG setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/CNE5T4oBgHgl3EQfTg-d/content/2301.05537v1.pdf'}
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diff --git a/D9E0T4oBgHgl3EQfQgCE/content/tmp_files/2301.02194v1.pdf.txt b/D9E0T4oBgHgl3EQfQgCE/content/tmp_files/2301.02194v1.pdf.txt
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@@ -0,0 +1,1419 @@
+arXiv:2301.02194v1  [cs.PL]  5 Jan 2023
+Builtin Types viewed as Inductive Families
+Guillaume Allais
+January 6, 2023
+Abstract
+State of the art optimisation passes for dependently typed languages
+can help erase the redundant information typical of invariant-rich data
+structures and programs. These automated processes do not dramatically
+change the structure of the data, even though more efficient representa-
+tions could be available.
+Using Quantitative Type Theory, we demonstrate how to define an
+invariant-rich, typechecking time data structure packing an efficient run-
+time representation together with runtime irrelevant invariants. The com-
+piler can then aggressively erase all such invariants during compilation.
+Unlike other approaches, the complexity of the resulting representation
+is entirely predictable, we do not require both representations to have the
+same structure, and yet we are able to seamlessly program as if we were
+using the high-level structure.
+1
+Introduction
+Dependently typed languages have empowered users to precisely describe their
+domain of discourse by using inductive families [Dyb94]. Programmers can bake
+crucial invariants directly into their definitions thus refining both their func-
+tions’ inputs and outputs. The constrained inputs allow them to only consider
+the relevant cases during pattern matching, while the refined outputs guaran-
+tee that client code can safely rely on the invariants being maintained. This
+programming style is dubbed ‘correct by construction’.
+However, relying on inductive families can have a non-negligible runtime
+cost if the host language is compiling them na¨ıvely. And even state of the art
+optimisation passes for dependently typed languages cannot make miracles: if
+the source code is not efficient, the executable will not be either.
+A state of the art compiler will for instance successfully compile length-
+indexed lists to mere lists thus reducing the space complexity from quadratic
+to linear in the size of the list. But, confronted with a list of booleans whose
+length is statically known to be less than 64, it will fail to pack it into a single
+machine word thus spending linear space when constant would have sufficed.
+In section 2, we will look at an optimisation example that highlights both
+the strengths and the limitations of the current state of the art when it comes to
+removing the runtime overheads potentially incurred by using inductive families.
+1
+
+In section 3 we will give a quick introduction to Quantitative Type Theory,
+the expressive language that grants programmers the ability to have both strong
+invariants and, reliably, a very efficient runtime representation.
+In section 4 we will look at an inductive family that we use in a performance-
+critical way in the TypOS project [AAM+22] and whose compilation suffers
+from the limitations highlighted in section 2. Our current and unsatisfactory
+approach is to rely on the safe and convenient inductive family when experi-
+menting in Agda and then replace it with an unsafe but vastly more efficient
+representation in our actual Haskell implementation.
+Finally in section 5, we will study the actual implementation of our efficient
+and invariant-rich solution implemented in Idris 2. We will also demonstrate
+that we can recover almost all the conveniences of programming with inductive
+families thanks to smart constructors and views.
+2
+An Optimisation Example
+The prototypical examples of the na¨ıve compilation of inductive families being
+inefficient are probably the types of vectors (Vect) and finite numbers (Fin).
+Their interplay is demonstrated by the lookup function.
+Let us study this
+example and how successive optimisation passes can, in this instance, get rid of
+the overhead introduced by using indexed families over plain data.
+A vector is a length-indexed list. The type Vect is parameterised by the
+type of values it stores and indexed over a natural number corresponding to its
+length. More concretely, its Nil constructor builds an empty vector of size Z
+(i.e. zero), and its (::) (pronounced ‘cons’) constructor combines a value of
+type a (the head) and a subvector of size n (the tail) to build a vector of size (S
+n) (i.e. successor of n).
+data Vect : Nat -> Type -> Type where
+Nil : Vect Z a
+(::) : a -> Vect n a -> Vect (S n) a
+The size n is not explicitly bound in the type of (::). In Idris 2, this means
+that it is automatically generalised over in a prenex manner reminiscent of the
+handling of free type variables in languages in the ML family. This makes it
+an implicit argument of the constructor.
+Consequently, given that Nat is a
+type of unary natural numbers, a na¨ıve runtime representation of a (Vect n a)
+would have a size quadratic in n. A smarter representation with perfect sharing
+would still represent quite an overhead as observed by Brady, McBride, and
+McKinna [BMM03].
+A finite number is a number known to be strictly smaller than a given natural
+number. The type Fin is indexed by said bound. Its Z constructor models 0 and
+is bound by any non-zero bound, and its S constructor takes a number bound
+by n and returns its successor, bound by (1 + n). A na¨ıve compilation would
+here also lead to a runtime representation suffering from a quadratic blowup.
+2
+
+data Fin : Nat -> Type where
+Z : Fin (S n)
+S : Fin n -> Fin (S n)
+This leads us to the definition of the lookup function. Provided a vector of
+size n and a finite number k bound by this same n, we can define a total function
+looking up the value stored at position k in the vector. It is guaranteed to return
+a value. Note that we do not need to consider the case of the empty vector in the
+pattern matching clauses as all of the return types of the Fin constructors force
+the index to be non-zero and, because the vector and the finite number talk
+about the same n, having an empty vector would automatically imply having a
+value of type (Fin 0) which is self-evidently impossible.
+lookup : Vect n a -> Fin n -> a
+lookup (x :: _) Z = x
+lookup (_ :: xs) (S k) = lookup xs k
+Thanks to our indexed family, we have gained the ability to define a function
+that cannot possibly fail, as well as the ability to only talk about the pattern
+matching clauses that make sense. This seemed to be at the cost of efficiency but
+luckily for us there has already been extensive work on erasure to automatically
+detect redundant data [BMM03] or data that will not be used at runtime [Tej20].
+2.1
+Optimising Vect, Fin, and lookup
+An analysis in the style of Brady, McBride, and McKinna’s [BMM03] can solve
+the quadratic blowup highlighted above by observing that the natural number
+a vector is indexed by is entirely determined by the spine of the vector. In
+particular, the length of the tail does not need to be stored as part of the
+constructor: it can be reconstructed as the predecessor of the length of the
+overall vector. As a consequence, a vector can be adequately represented at
+runtime by a pair of a natural number and a list. Similarly a bounded number
+can be adequately represented by a pair of natural numbers. Putting all of this
+together and remembering that the vector and the finite number share the same
+n, lookup can be compiled to a function taking two natural numbers and a list.
+In Idris 2 we would write the optimised lookup as follows (we use the partial
+keyword because this transformed version is not total at that type).
+partial
+lookup : (n : Nat) -> List a -> Nat -> a
+lookup (S n) (x :: _) Z = x
+lookup (S n) (_ :: xs) (S k) = lookup n xs k
+We can see in the second clause that the recursive call is performed on the tail
+of the list (formerly vector) and so the first argument to lookup corresponding
+to the vector’s size is decreased by one. The invariant, despite not being explicit
+anymore, is maintained.
+3
+
+A Tejiˇsˇc´ak-style analysis [Tej20] can additionally notice that the lookup func-
+tion never makes use of the bound’s value and drop it entirely. This leads to
+the lookup function on vectors being compiled to its partial-looking counterpart
+acting on lists.
+partial
+lookup : List a -> Nat -> a
+lookup (x :: _) Z = x
+lookup (_ :: xs) (S k) = lookup xs k
+Even though this is in our opinion a pretty compelling example of erasing
+away the apparent complexity introduced by inductive families, this approach
+has two drawbacks.
+Firstly, it relies on the fact that the compiler can and will automatically
+perform these optimisations. But nothing in the type system prevents users from
+inadvertently using a value they thought would get erased, thus preventing the
+Tejiˇsˇc´ak-style optimisation from firing. In performance-critical settings, users
+may rather want to state their intent explicitly and be kept to their word by
+the compiler in exchange for predictable and guaranteed optimisations.
+Secondly, this approach is intrinsically limited to transformations that pre-
+serve the type’s overall structure: the runtime data structures are simpler but
+very similar still. We cannot expect much better than that. It is so far unre-
+alistic to expect e.g. a change of representation to use a balanced binary tree
+instead of a list in order to get logarithmic lookups rather than linear ones.
+2.2
+No Magic Solution
+Even if we are able to obtain a more compact representation of the inductive
+family at runtime through enough erasure, this does not guarantee runtime
+efficiency. As the Coq manual [CDT22] reminds its users, extraction does not
+magically optimise away a user-defined quadratic multiplication algorithm when
+extracting unary natural numbers to an efficient machine representation. In
+a pragmatic move, Coq, Agda, and Idris 2 all have ad-hoc rules to replace
+convenient but inefficiently implemented numeric functions with asymptotically
+faster counterparts in the target language.
+However this approach is not scalable: if we may be willing to extend our
+trusted core to a high quality library for unbounded integers, we do not want to
+replace our code only proven correct thanks to complex invariants with a wildly
+different untrusted counterpart purely for efficiency reasons.
+In this paper we use Quantitative Type Theory [McB16, Atk18] as imple-
+mented in Idris 2 [Bra21] to bridge the gap between an invariant-rich but in-
+efficient representation based on an inductive family and an unsafe but effi-
+cient implementation using low-level primitives. Inductive families allow us to
+view [Wad87, MM04] the runtime relevant information encoded in the low-level
+and efficient representation as an information-rich compile time data structure.
+Moreover the quantity annotations guarantee that this additional information
+4
+
+will be erased away during compilation.
+3
+Some Key Features of Idris 2
+Idris 2 implements Quantitative Type Theory, a Martin-L¨of type theory enriched
+with a semiring of quantities classifying the ways in which values may be used.
+In a type, each binder is annotated with the quantity by which its argument
+must abide.
+3.1
+Quantities
+A value may be runtime irrelevant, linear, or unrestricted.
+Runtime irrelevant values (0 quantity) cannot possibly influence control flow
+as they will be erased entirely during compilation. This forces the language
+to impose strong restrictions on pattern-matching over these values. Typical
+examples are types like the a parameter in (List a), or indices like the natural
+number n in (Vect n a). These are guaranteed to be erased at compile time.
+The advantage over a Tejiˇsˇc´ak-style analysis is that users can state their intent
+that an argument ought to be runtime irrelevant and the language will insist
+that it needs to be convinced it indeed is.
+Linear values (1 quantity) have to be used exactly once. Typical examples
+include the %World token used by Idris 2 to implement the IO monad `a la Haskell,
+or file handles that cannot be discarded without first explicitly closing the file.
+At runtime these values can be updated destructively. We will not use linearity
+in this paper.
+Last, unrestricted values (denoted by no quantity annotation) can flow into
+any position, be duplicated or thrown away. They are the usual immutable
+values of functional programming.
+The most basic of examples mobilising both the runtime irrelevance and
+unrestricted quantities is the identity function.
+id : {0 a : Type} -> (x : a) -> a
+id x = x
+Its type starts with a binder using curly braces. This means it introduces
+an implicit variable that does not need to be filled in by the user at call sites
+and will be reconstructed by unification. The variable it introduces is named
+a and has type Type. It has the 0 quantity annotation which means that this
+argument is runtime irrelevant and so will be erased during compilation.
+The second binder uses parentheses. It introduces an explicit variable whose
+name is x and whose type is the type a that was just bound. It has no quantity
+annotation which means it will be an unrestricted variable.
+Finally the return type is the type a bound earlier. This is, as expected, a
+polymorphic function from a to a. It is implemented using a single clause that
+binds x on the left-hand side and immediately returns it on the right-hand side.
+5
+
+If we were to try to annotate the binder for x with a 0 quantity to make
+it runtime irrelevant then Idris 2 would rightfully reject the definition.
+The
+following failing block shows part of the error message complaining that x
+cannot be used at an unrestricted quantity on the right-hand side.
+failing "x is not accessible in this context."
+id : {0 a : Type} -> (0 x : a) -> a
+id x = x
+3.2
+Proof Search
+In Idris 2, Haskell-style ad-hoc polymorphism [WB89] is superseded by a more
+general proof search mechanism.
+Instead of having blessed notions of type
+classes, instances and constraints, the domain of any dependent function type
+can be marked as auto. This signals to the compiler that the corresponding
+argument will be an implicit argument and that it should not be reconstructed
+by unification alone but rather by proof search. The search algorithm will use
+the appropriate user-declared hints as well as the local variables in scope.
+By default, a datatype’s constructors are always added to the database of
+hints. And so the following declaration brings into scope both an indexed family
+So of proofs that a given boolean is True, and a unique constructor Oh that is
+automatically added as a hint.
+data So : Bool -> Type where
+Oh : So True
+As a consequence, we can for instance define a record type specifying what
+it means for n to be an even number by storing its half together with a proof
+that is both runtime irrelevant and filled in by proof search. Because (2 * 3 ==
+6) computes to True, Idris 2 is able to fill-in the missing proof in the definition
+of even6 using the Oh hint.
+record Even (n : Nat) where
+constructor MkEven
+half : Nat
+{auto 0 prf : So (2 * half == n)}
+even6 : Even 6
+even6 = MkEven { half = 3 }
+We will use both So and the auto mechanism in section 5.3.
+3.3
+Application: Vect, as List
+We can use the features of Quantitative Type Theory to give an implementa-
+tion of Vect that is guaranteed to erase to a List at runtime independently of
+the optimisation passes implemented by the compiler. The advantage over the
+optimisation passes described in section 2 is that the user has control over the
+6
+
+runtime representation and does not need to rely on these optimisations being
+deployed by the compiler.
+The core idea is to make the slogan ‘a vector is a length-indexed list’ a
+reality by defining a record packing together the encoding as a list and a proof
+its length is equal to the expected Nat index. This proof is marked as runtime
+irrelevant to ensure that the list is the only thing remaining after compilation.
+record Vect (n : Nat) (a : Type) where
+constructor MkVect
+encoding : List a
+0 valid : length encoding === n
+Smart constructors
+Now that we have defined vectors, we can recover the
+usual building blocks for vectors by defining smart constructors, that is to say
+functions Nil and (::) that act as replacements for the inductive family’s data
+constructors.
+Nil : Vect Z a
+Nil = MkVect [] Refl
+The smart constructor Nil returns an empty vector. It is, unsurprisingly,
+encoded as the empty list ([]). Because (length []) statically computes to Z,
+the proof that the encoding is valid can be discharged by reflexivity.
+(::) : a -> Vect n a -> Vect (S n) a
+x :: MkVect xs eq = MkVect (x :: xs) (cong S eq)
+Using (::) we can combine a head and a tail of size n to obtain a vector of
+size (S n). The encoding is obtained by consing the head in front of the tail’s
+encoding and the proof this is valid (cong S eq) uses the fact that propositional
+equality is a congruence and that (length (x :: xs)) computes to (S (length
+xs)).
+View
+Now that we know how to build vectors, we demonstrate that we can
+also take them apart using a view.
+A view for a type T , in the sense of Wadler [Wad87], and as refined by
+McBride and McKinna [MM04], is an inductive family V indexed by T together
+with a total function mapping every element t of T to a value of type (V t). This
+simple gadget provides a powerful, user-extensible, generalisation of pattern-
+matching. Patterns are defined inductively as either a pattern variable, a forced
+term (i.e. an arbitrary expression that is determined by a constraint arising
+from another pattern), or a data constructor fully applied to subpatterns. In
+contrast, the return indices of an inductive family’s constructors can be arbitrary
+expressions.
+In the case that interests us, the view allows us to emulate ‘matching’ on
+which of the two smart constructors Nil or (::) was used to build the vector
+being taken apart.
+7
+
+data View : Vect n a -> Type where
+Nil : View Nil
+(::) : (x : a) -> (xs : Vect n a) -> View (x :: xs)
+The inductive family View is indexed by a vector and has two constructors
+corresponding to the two smart constructors. We use Idris 2’s overloading capa-
+bilities to give each of the View’s constructors the name of the smart constructor
+it corresponds to. By pattern-matching on a value of type (View xs), we will be
+able to break xs into its constitutive parts and either observe it is equal to Nil
+or recover its head and its tail.
+view : (xs : Vect n a) -> View xs
+view (MkVect [] Refl) = Nil
+view (MkVect (x :: xs) Refl) = x :: MkVect xs Refl
+The function view demonstrates that we can always tell which constructor
+was used by inspecting the encoding list. If it is empty, the vector was built
+using the Nil smart constructor. If it is not then we got our hands on the
+head and the tail of the encoding and (modulo some re-wrapping of the tail)
+they are effectively the head and the tail that were combined using the smart
+constructor.
+3.3.1
+Application: map
+We can then use these constructs to implement the function map on vectors
+without ever having to explicitly manipulate the encoding.
+The maximally
+sugared version of map is as follows:
+map : (a -> b) -> Vect n a -> Vect n b
+map f xs@_ with (view xs)
+_ | [] = []
+_ | hd :: tl = f hd :: map f tl
+On the left-hand side the view lets us seamlessly pattern-match on the input
+vector. Using the with keyword we have locally modified the function defini-
+tion so that it takes an extra argument, here the result of the intermediate
+computation (view xs). Correspondingly, we have two clauses matching on this
+extra argument; the symbol | separates the original left-hand side (here elided
+using _ because it is exactly the same as in the parent clause) from the addi-
+tional pattern. This pattern can either have the shape [] or (hd :: tl) and,
+correspondingly, we learn that xs is either [] or (hd :: tl).
+On the right-hand side the smart constructors let us build the output vec-
+tor. Mapping a function over the empty vector yields the empty vector while
+mapping over a cons node yields a cons node whose head and tail have been
+appropriately modified.
+This sugared version of map is equivalent to the following more explicit one:
+8
+
+map : (a -> b) -> Vect n a -> Vect n b
+map f xs with (view xs)
+map f .([]) | [] = []
+map f .(hd :: tl) | hd :: tl = f hd :: map f tl
+In the parent clause we have explicitly bound xs instead of merely introduc-
+ing an alias for it by writing (xs@ ) and so we will need to be explicit about the
+ways in which this pattern is refined in the two with-clauses.
+In the with-clauses, we have explicitly repeated the refined version of the
+parent clause’s left-hand side. In particular we have used dotted patterns to
+insist that xs is now entirely forced by the match on the result of (view xs).
+We have seen that by matching on the result of the (view xs) call, we get to
+‘match’ on xs as if Vect were an inductive type. This is the power of views.
+3.3.2
+Application: lookup
+The type (Fin n) can similarly be represented by a single natural number and
+a runtime irrelevant proof that it is bound by n. We leave these definitions
+out, and invite the curious reader to either attempt to implement them for
+themselves or look at the accompanying code.
+Bringing these definitions together, we can define a lookup function which
+is similar to the one defined in section 2.
+lookup : Vect n a -> Fin n -> a
+lookup xs@_ k@_ with (view xs) | (view k)
+_ | hd :: _ | Z = hd
+_ | _ :: tl | S k’ = lookup tl k’
+We are seemingly using view at two different types (Vect and Fin respec-
+tively) but both occurrences actually refer to separate functions: Idris 2 lets us
+overload functions and performs type-directed disambiguation.
+For pedagogical purposes, this sugared version of lookup can also be ex-
+panded to a more explicit one that demonstrates the views’ power.
+lookup : Vect n a -> Fin n -> a
+lookup xs k with (view xs) | (view k)
+lookup .(hd :: tl) .(Z) | hd :: tl | Z = hd
+lookup .(hd :: tl) .(S k’) | hd :: tl | S k’ = lookup tl k’
+The main advantage of this definition is that, based on its type alone, we
+know that this function is guaranteed to be processing a list and a single natural
+number at runtime. This efficient runtime representation does not rely on the
+assumption that state of the art optimisation passes will be deployed.
+We have seen some of Idris 2’s powerful features and how they can be lever-
+aged to empower users to control the runtime representation of the inductive
+families they manipulate. This simple example only allowed us to reproduce
+the performance that could already be achieved by compilers deploying state of
+the art optimisation passes. In the following sections, we are going to see how
+9
+
+we can use the same core ideas to compile an inductive family to a drastically
+different runtime representation while keeping good high-level ergonomics.
+4
+Thinnings, cooked two ways
+We experienced a major limitation of compilation of inductive families during
+our ongoing development of TypOS [AAM+22], a domain specific language to
+define concurrent typecheckers and elaborators.
+Core to this project is the defi-
+nition of actors manipulating a generic notion of syntax with binding. Internally
+the terms of this syntax with binding are based on a co-de Bruijn representa-
+tion (an encoding we will explain below) which relies heavily on thinnings. A
+thinning (also known as an Order Preserving Embedding [Cha09]) between a
+source and a target scope is an order preserving injection of the smaller scope
+into the larger one. They are usually represented using an inductive family.
+The omnipresence of thinnings in the co-de Bruijn representation makes their
+runtime representation a performance critical matter.
+Let us first remind the reader of the structure of abstract syntax trees in a
+named, a de Bruijn, and a co-de Bruijn representation. We will then discuss two
+representations of thinnings: a safe and convenient one as an inductive family,
+and an unsafe but efficient encoding as a pair of arbitrary precision integers.
+4.1
+Named, de Bruijn, and co-de Bruijn syntaxes
+In this section we will use the S combinator (λg.λf.λx.gx(fx)) as a running
+example and represent terms using a syntax tree whose constructor nodes are
+circles and variable nodes are squares.
+To depict the S combinator we will
+only need λ-abstraction and application (rendered $) nodes. A constructor’s
+arguments become its children in the tree. The tree is laid out left-to-right and
+a constructor’s arguments are displayed top-to-bottom.
+Named syntax
+The first representation is using explicit names. Each binder
+has an associated name and each variable node carries a name. A variable refers
+to the closest enclosing binder which happens to be using the same name.
+λg.
+λf.
+λx.
+$
+$
+g
+x
+$
+f
+x
+To check whether two terms are structurally equivalent (α-equivalence) po-
+tentially requires renaming bound names. In order to have a simple and cheap
+α-equivalence check we can instead opt for a nameless representation.
+10
+
+De Bruijn syntax
+An abstract syntax tree based on de Bruijn indices [dB72]
+replaces names with natural numbers counting the number of binders separating
+a variable from its binding site. The S combinator is now written (λ λ λ 2 0 (1 0)).
+You can see in the following graphical depiction that λ-abstractions do not
+carry a name anymore and that variables are simply pointing to the binder
+that introduced them.
+We have left the squares empty but in practice the
+various coloured arrows would be represented by a natural number. For instance
+the dashed magenta one corresponds to 1 because you need to ignore one λ-
+abstraction (the orange one) on your way towards the root of the tree before
+you reach the corresponding magenta binder.
+λ.
+λ.
+λ.
+$
+$
+$
+To check whether a subterm does not mention a given set of variables (a
+thickening test, the opposite of a thinning which extends the current scope with
+unused variables), you need to traverse the whole term.
+In order to have a
+simple cheap thickening test we can ensure that each subterms knows precisely
+what its support is and how it embeds in its parent’s.
+Co-de Bruijn syntax
+In a co-de Bruijn representation [McB18] each subterm
+selects exactly the variables that stay in scope for that term, and so a variable
+constructor ultimately refers to the only variable still in scope by the time it is
+reached. This representation ensures that we know precisely what the scope of
+a given term currently is.
+In the following graphical rendering, we represent thinnings as lists of full
+(•) or empty (◦) discs depending on whether the corresponding variable is either
+kept or discarded. For instance the thinning represented by ◦•• throws the blue
+variable away, and keeps both the magenta and orange ones.
+λ.
+λ.
+λ.
+$
+$
+$
+•
+••
+•••
+◦••
+•◦•
+•◦
+◦•
+•◦
+◦•
+11
+
+We can see that in such a representation, each node in the tree stores one
+thinning per subterm. This will not be tractable unless we have an efficient
+representation of thinnings.
+4.2
+The Performance Challenges of co-de Bruijn
+Using the co-de Bruijn approach, a term in an arbitrary context is repre-
+sented by the pairing of a term in co-de Bruijn syntax with a thinning from
+its support into the wider scope. Having such a precise handle on each term’s
+support allows us to make operations such as thinning, substitution, unification,
+or common sub-expression elimination more efficient.
+Thinning a term does not require us to traverse it anymore. Indeed, embed-
+ding a term in a wider context will not change its support and so we can simply
+compose the two thinnings while keeping the term the same.
+Substitution can avoid traversing subterms that will not be changed. Indeed,
+it can now easily detect when the substitution’s domain does not intersect with
+the subterm’s support.
+Unification requires performing thickening tests when we want to solve a
+metavariable declared in a given context with a terms seemingly living in a
+wider one. We once more do not need to traverse the term to perform this test,
+and can simply check whether the outer thinning can be thickened.
+Common sub-expression elimination requires us to identify alpha-equivalent
+terms potentially living in different contexts. Using a de Bruijn representation,
+these can be syntactically different: a variable represented by the natural num-
+ber v in Γ would be (1+v) in Γ, σ but (2+v) in Γ, τ, ν. A co-de Bruijn represen-
+tation, by discarding all the variables not in the support, guarantees that we can
+once more use syntactic equality to detect alpha-equivalence. This encoding is
+used for instance (albeit unknowingly) by Maziarz, Ellis, Lawrence, Fitzgibbon,
+and Peyton-Jones in their ‘Hashing modulo alpha-equivalence’ work [MEL+21].
+For all of these reasons we have, as we mentioned earlier, opted for a co-de
+Bruijn representation in the implementation of TypOS [AAM+22].
+And so it
+is crucial for performance that we have a compact representation of thinnings.
+4.2.1
+Thinnings in TypOS
+We first carefully worked out the trickier parts of the implementation in Agda
+before porting the resulting code to Haskell. This process highlighted a glaring
+gap between on the one hand the experiments done using a strongly typed
+inductive representation of thinnings and on the other hand their more efficient
+but unsafe encoding in Haskell.
+Agda
+The Agda-based experiments use inductive families that make the key
+invariants explicit which helps tracking complex constraints and catches design
+flaws at typechecking time. The indices guarantee that we always transform the
+12
+
+thinnings appropriately when we add or remove bound variables. In Idris 2, the
+inductive family representation of thinnings would be written:
+data Thinning : (sx, sy : SnocList a) -> Type where
+Done : Thinning [<] [<]
+Keep : Thinning sx sy -> (0 x : a) -> Thinning (sx :< x) (sy :< x)
+Drop : Thinning sx sy -> (0 x : a) -> Thinning sx (sy :< x)
+The Thinning family is indexed by two scopes (represented as snoclists i.e. lists
+that are extended from the right, just like contexts in inference rules): sx the
+tighter scope and sy the wider one.
+The Done constructor corresponds to a
+thinning from the empty scope to itself ([<] is Idris 2 syntactic sugar for the
+empty snoclist), and Keep and Drop respectively extend a given thinning by
+keeping or dropping the most local variable (:< is the ‘snoc’ constructor, a sort
+of flipped ‘cons’). The ‘name’ (x of type a) is marked with the quantity 0 to
+ensure it is erased at compile time (cf. section 3).
+During compilation, Idris 2 would erase the families’ indices as they are
+forced (in the sense of Brady, McBride, and McKinna [BMM03]), and drop the
+constructor arguments marked as runtime irrelevant. The resulting inductive
+type would be the following simple data type.
+data Thinning = Done | Keep Thinning | Drop Thinning
+At runtime this representation is therefore essentially a linked list of booleans
+(Done being Nil, and Keep and Drop respectively (True ::) and (False ::)).
+Haskell
+The Haskell implementation uses this observation and picks a packed
+encoding of this list of booleans as a pair of integers. One integer represents the
+length n of the list, and the other integer’s n least significant bits encode the
+list as a bit pattern where 1 is Keep and 0 is Drop.
+Basic operations on thinnings are implemented by explicitly manipulating
+individual bits. It is not indexed and thus all the invariant tracking has to be
+done by hand. This has led to numerous and hard to diagnose bugs.
+4.2.2
+Thinnings in Idris 2
+Idris 2 is a self-hosting language whose core datatype is currently based on a
+well-scoped de Bruijn representation. This precise indexing of terms by their
+scope helped entirely eliminate a whole class of bugs that plagued Idris 1’s
+unification machinery.
+If we were to switch to a co-de Bruijn representation for our core language
+we would want, and should be able, to have the best of both worlds: a safe and
+efficient representation!
+Thankfully Idris 2 implements Quantitative Type Theory (QTT) which gives
+us a lot of control over what is to be runtime relevant and what is to be erased
+during compilation. This should allow us to insist on having a high-level in-
+terface that resembles an inductive family while ensuring that everything but
+13
+
+a pair of integers is erased at compile time. We will exploit the key features of
+QTT presented in section 3 to have our cake and eat it.
+5
+An Efficient Invariant-Rich Representation
+We can combine both approaches highlighted in section 4.2 by defining a record
+parameterised by a source (sx) and target (sy) scopes corresponding to the two
+ends of the thinnings, just like we would for the inductive family. This record
+packs two numbers and a runtime irrelevant proof.
+Firstly, we have a natural number called bigEnd corresponding to the size of
+the big end of the thinning (sy). We are happy to use a (unary) natural number
+here because we know that Idris 2 will compile it to an unbounded integer.
+Secondly, we have an integer called encoding corresponding to the thinning
+represented as a bit vector stating, for each variable, whether it is kept or
+dropped.
+We only care about the integer’s bigEnd least significant bits and
+assume the rest is set to 0.
+Thirdly, we have a runtime irrelevant proof invariant that encoding is in-
+deed a valid encoding of size bigEnd of a thinning from sx to sy. We will explore
+the definition of the relation Invariant later on in section 5.3.
+record Th {a : Type} (sx, sy : SnocList a) where
+constructor MkTh
+bigEnd : Nat
+encoding : Integer
+0 invariant : Invariant bigEnd encoding sx sy
+The first sign that this definition is adequate is our ability to construct any
+valid thinning. We demonstrate it is the case by introducing functions that act
+as smart constructor analogues for the inductive family’s data constructors.
+5.1
+Smart Constructors for Th
+The first and simplest one is done, a function that packs a pair of 0 (the size of
+the big end, and the empty encoding) together with a proof that it is an adequate
+encoding of the thinning from the empty scope to itself. In this instance, the
+proof is simply the Done constructor.
+done : Th [<] [<]
+done = MkTh { bigEnd = 0, encoding = 0, invariant = Done }
+To implement both keep and drop, we are going to need to perform bit-level
+manipulations. These are made easy by Idris 2’s Bits interface which provides us
+with functions to shift the bit patterns left or right (shiftl, shiftr), set or clear
+bits at specified positions (setBit, clearBit), take bitwise logical operations like
+disjunction (.|.) or conjunction (.&.), etc.
+14
+
+In both keep and drop, we need to extend the encoding with an additional
+bit. For this purpose we introduce the cons function which takes a bit b and an
+existing encoding bs and returns the new encoding bs·b.
+cons : Bool -> Integer -> Integer
+cons b bs = let bs0 = bs ‘shiftL‘ 1 in
+if b then (bs0 ‘setBit‘ 0) else bs0
+No matter what the value of the new bit is, we start by shifting the encoding
+to the left to make space for it; this gives us bs0 which contains the bit pattern
+bs·0. If the bit is True then we need to additionally set the bit at position 0
+to obtain bs·1. Otherwise if the bit is False, we can readily return the bs·0
+encoding obtained by left shifting. The correctness of this function is backed by
+two lemma: testing the bit at index 0 after consing amounts to returning the
+cons’d bit, and shifting the cons’d encoding to the right takes us back to the
+unextended encoding.
+testBit0Cons : (b : Bool) -> (bs : Integer) ->
+testBit (cons b bs) 0 === b
+consShiftR : (b : Bool) -> (bs : Integer) ->
+(cons b bs) ‘shiftR‘ 1 === bs
+The keep smart constructor demonstrates that from a thinning from sx to
+sy and a runtime irrelevant variable x we can compute a thinning from the
+extended source scope (sx :< x) to the target scope (sy :< x) where x was kept.
+keep : Th sx sy -> (0 x : a) -> Th (sx :< x) (sy :< x)
+keep th x = MkTh
+{ bigEnd = S (th .bigEnd)
+, encoding = cons True (th .encoding)
+, invariant =
+let 0 b = eqToSo $ testBit0Cons True (th .encoding) in
+Keep (rewrite consShiftR True (th .encoding) in th.invariant) x
+}
+The outer scope has grown by one variable and so we increment bigEnd. The
+encoding is obtained by cons-ing the boolean True to record the fact that this
+new variable is kept. Finally, we use the two lemmas shown above to convince
+Idris 2 the invariant has been maintained.
+Similarly the drop function demonstrates that we can compute a thinning
+getting rid of the variable x freshly added to the target scope.
+15
+
+drop : Th sx sy -> (0 x : a) -> Th sx (sy :< x)
+drop th x = MkTh
+{ bigEnd = S (th .bigEnd)
+, encoding = cons False (th .encoding)
+, invariant =
+let 0 prf = testBit0Cons False (th .encoding)
+0 nb = eqToSo $ cong not prf in
+Drop (rewrite consShiftR False (th .encoding) in th .invariant) x
+}
+We once again increment the bigEnd, use cons to record that the variable is
+being discarded and use the lemmas ensuring its correctness to convince Idris 2
+the invariant is maintained.
+We can already deploy these smart constructors to implement functions pro-
+ducing thinnings. We use which as our example. It is a filter-like function that
+returns a dependent pair containing the elements that satisfy a boolean predi-
+cate together with a proof that there is a thinning embedding them back into
+the input snoclist.
+which : (a -> Bool) -> (sy : SnocList a) ->
+(sx : SnocList a ** Th sx sy)
+which p [<] = ([<] ** done)
+which p (sy :< y) =
+let (sx ** th) = which p sy in
+if p y then (sx :< y ** keep th y)
+else (sx ** drop th y)
+If the input snoclist is empty then the output shall also be, and done builds
+a thinning from [<] to itself. If it is not empty we can perform a recursive call
+on the tail of the snoclist and then depending on whether the predicates holds
+true of the head we can either keep or drop it.
+We are now equipped with these smart constructors that allow us to seam-
+lessly build thinnings.
+To recover the full expressive power of the inductive
+family, we also need to be able to take these thinnings apart. We are now going
+to tackle this issue.
+5.2
+Pattern Matching on Th
+The View family is a sum type indexed by a thinning. It has one data constructor
+associated to each smart constructor and storing its arguments.
+data View : Th sx sy -> Type where
+Done : View done
+Keep : (th : Th sx sy) -> (0 x : a) -> View (keep th x)
+Drop : (th : Th sx sy) -> (0 x : a) -> View (drop th x)
+The accompanying view function witnesses the fact that any thinning arises
+as one of these three cases.
+16
+
+view : (th : Th sx sy) -> View th
+We show the implementation of view in its entirety but leave out the tech-
+nical auxiliary lemma it invokes. The interested reader can find them in the
+accompanying material. We will however inspect the code view compiles to af-
+ter erasure in section 5.5 to confirm that these auxiliary definitions do not incur
+any additional runtime cost.
+We first start by pattern matching on the bigEnd of the thinning. If it is 0
+then we know the thinning has to be the empty thinning. Thanks to an inversion
+lemma called isDone, we can collect a lot of equality proofs: the encoding bs has
+to be 0, the source and target scopes sx and sy have to be the empty snoclists,
+and the proof prf of the invariant has to be of a specific shape. Rewriting by
+these equalities changes the goal type enough for the typechecker to ultimately
+see that the thinning was constructed using the done smart constructor and so
+we can use the view’s Done constructor.
+view (MkTh 0 bs prf) =
+let 0 eqs = isDone prf in
+rewrite bsIsZero eqs in
+rewrite fstIndexIsLin eqs in
+rewrite sndIndexIsLin eqs in
+rewrite invariantIsDone eqs in
+Done
+In case the thinning is non-empty, we need to inspect the 0-th bit of the
+encoding to know whether it keeps or discards its most local variable. This is
+done by calling the choose function which takes a boolean b and returns a value
+of type (Either (So b) (So (not b)) i.e. we not only inspect the boolean but also
+record which value we got in a proof using the So family introduced in section 3.
+view (MkTh (S i) bs prf) = case choose (testBit bs Z) of
+If the bit is set then we know the variable is kept. And so we can invoke an
+inversion lemma that will once again provide us with a lot of equalities that we
+immediately deploy to reshape the goal’s type. This ultimately lets us assemble
+a sub-thinning and use the view’s Keep constructor.
+Left so =>
+let 0 eqs = isKeep prf so in
+rewrite fstIndexIsSnoc eqs in
+rewrite sndIndexIsSnoc eqs in
+rewrite invariantIsKeep eqs in
+rewrite isKeepInteger bs so in
+let th : Th eqs.fstIndexTail eqs.sndIndexTail
+th = MkTh i (bs ‘shiftR‘ 1) eqs.subInvariant in
+cast $ Keep th eqs.keptHead
+If the bit is not set then we learn that the thinning was constructed using
+17
+
+drop. We can once again use an inversion lemma to rearrange the goal and
+finally invoke the view’s Drop constructor.
+Right soNot =>
+let 0 eqs = isDrop prf soNot in
+rewrite sndIndexIsSnoc eqs in
+rewrite invariantIsDrop eqs in
+rewrite isDropInteger bs soNot in
+let th : Th sx eqs.sndIndexTail
+th = MkTh i (bs ‘shiftR‘ 1) eqs.subInvariant in
+cast $ Drop th eqs.keptHead
+We can readily use this function to implement pattern matching functions
+taking a thinning apart. We can for instance define kept, the function that
+counts the number of keep smart constructors used when manufacturing the
+input thinning and returns a proof that this is exactly the length of the source
+scope sx.
+kept : Th sx sy -> (n : Nat ** length sx === n)
+kept th = case view th of
+Done
+=> (0 ** Refl)
+Keep th x => let (n ** eq) = kept th in
+(S n ** cong S eq)
+Drop th x => kept th
+We proceed by calling the view function on the input thinning which im-
+mediately tells us that we only have three cases to consider. The Done case is
+easily handled because the branch’s refined types inform us that both sx and
+sy are the empty snoclist [<] whose length is evidently 0. In the Keep branch
+we learn that sx has the shape (_ :< x) and so we must return the successor of
+whatever the result of the recursive call gives us. Finally in the Drop case, sx
+is untouched and so a simple recursive call suffices. Note that the function is
+correctly detected as total because the target scope sy is indeed getting struc-
+turally smaller at every single recursive call. It is runtime irrelevant but it can
+still be successfully used as a termination measure by the compiler.
+5.3
+The Invariant Relation
+We have shown the user-facing Th and have claimed that it is possible to define
+smart constructors done, keep, and drop, as well as a view function. This should
+become apparent once we show the actual definition of Invariant.
+5.3.1
+Definition of Invariant
+The relation maintains the invariant between the record’s fields bigEnd (a Nat)
+and encoding (an Integer) and the index scopes sx and sy. Its definition can
+favour ease-of-use of runtime efficiency because we statically know that all of
+18
+
+the Invariant proofs will be erased during compilation.
+data Invariant : (i : Nat) -> (bs : Integer) ->
+(sx, sy : SnocList a) -> Type where
+Done : Invariant Z 0 [<] [<]
+Keep : Invariant i (bs ‘shiftR‘ 1) sx sy -> (0 x : a) ->
+{auto 0 b
+: So (testBit bs Z)} ->
+Invariant (S i) bs (sx :< x) (sy :< x)
+Drop : Invariant i (bs ‘shiftR‘ 1) sx sy -> (0 x : a) ->
+{auto 0 nb : So (not (testBit bs Z))} ->
+Invariant (S i) bs sx (sy :< x)
+As always, the Done constructor is the simplest. It states that the thinning
+of size Z and encoded as the bit pattern 0 is the empty thinning.
+The Keep constructor guarantees that the thinning of size (S i) and encoding
+bs represents an injection from (sx :< x) to (sy :< x) provided that the bit at
+position Z of bs is set, and that the rest of the bit pattern (obtained by a right
+shift on bs) is a valid thinning of size i from sx to sy.
+The Drop constructor is structured the same way, except that it insists the
+bit at position Z should not be set.
+We can readily use this relation to prove that some basic encoding are valid
+representations of useful thinnings.
+5.3.2
+Examples of Invariant proofs
+For instance, we can always define a thinning from the empty scope to an
+arbitrary scope sy.
+none : (sy : SnocList a) -> Th [<] sy
+none sy = MkTh (length sy) 0 (none sy)
+The encoding of this thinning is 0 because every variable is being discarded
+and its bigEnd is the length of the outer scope sy. The proof that this encoding
+is valid is provided by the none lemma proven below. We once again use Idris 2’s
+overloading to give the same to functions that play similar roles but at different
+types.
+none : (sy : SnocList a) -> Invariant (length sy) 0 [<] sy
+none [<] = Done
+none (sy :< y) = Drop (none sy) y
+The proof proceeds by induction over the outer scope sy. If it is empty,
+we can simply use the constructor for the empty thinning. Otherwise we can
+invoke Drop on the induction hypothesis. This all typechecks because (testBit
+0 Z) computes to False and so the nb proof can be constructed automatically
+by Idris 2’s proof search (cf. section 3.2), and (0 ‘shiftR‘ 1) evaluates to 0
+which means the induction hypothesis has exactly the right type.
+19
+
+The definition of the identity thinning is a bit more involved. For a scope of
+size n, we are going to need to generate a bit pattern consisting of n ones. We
+define it in two steps. First, cofull defines a bit pattern of k zeros followed by
+infinitely many ones by shifting k places to the left a bit pattern of ones only.
+Then, we obtain full by taking the complement of cofull.
+cofull : Nat -> Integer
+cofull n = oneBits ‘shiftL‘ n
+full : Nat -> Integer
+full n = complement (cofull n)
+We can then define the identity thinning for a scope of size n by pairing
+(full n) as the encoding and n as the bigEnd.
+ones : (sx : SnocList a) -> Th sx sx
+ones sx = let n : Nat; n = length sx in MkTh n (full n) (ones sx)
+The bulk of the work is once again in the eponymous lemma proving that
+this encoding is valid.
+ones : (sx : SnocList a) ->
+let n = length sx in Invariant n (full n) sx sx
+ones [<] = Done
+ones (sx :< x) =
+let 0 nb = eqToSo (testBitFull (S (length sx)) Z) in
+Keep (rewrite shiftRFull (length sx) in ones sx) x
+This proof proceeds once more by induction on the scope. If the scope is
+empty then once again the constructor for the empty thinning will do. In the
+non-empty case, we first appeal to an auxiliary lemma (not shown here) to con-
+struct a proof nb that the bit at position Z for a non-zero full integer is known
+to be True. We then need to use another lemma to cast the induction hypothesis
+which mentions (full (length sx)) so that it may be used in a position where
+we expect a proof talking about (full (length (sx :< x)) ‘shiftR‘ 1).
+5.3.3
+Properties of the Invariant relation
+This relation has a lot of convenient properties.
+First, it is proof irrelevant: any two proofs that the same i, bs, sx, and sy
+are related are provably equal. Consequently, equality on Th values amounts to
+equality of the bigEnd and encoding values. In particular it is cheap to test
+whether a given thinning is the empty or the identity thinning.
+Second, it can be inverted [CT95] knowing only two bits: whether the natural
+number is empty and what the value of the bit at position Z of the encoding
+is. This is what allowed us to efficiently implement the view function by using
+these two checks and then inverting the Invariant proof to gain access to the
+proof that the remainder of the thinning’s encoding is valid. We will see in
+section 5.5 that this leads to efficient runtime code for the view.
+20
+
+5.4
+Choose Your Own Abstraction Level
+Access to both the high-level View and the internal Invariant relation means
+that programmers can pick the level of abstraction at which they want to work.
+They may need to explicitly manipulate bits to implement key operators that
+are used in performance-critical paths but can also stay at the highest level for
+more negligible operations, or when proving runtime irrelevant properties.
+In the previous section we saw simple examples of these bit manipulations
+when defining none (using the constant 0 bit pattern) and ones using bit shifting
+and complement to form an initial segment of 1s followed by 0s.
+Other natural examples include the meet and join of two thinnings sharing
+the same wider scope.
+The join can for instance be thought of either as a
+function defined by induction on the first thinning and case analysis on the
+second, emitting a Keep constructor whenever either of the inputs does. Or we
+can observe that the bit pattern in the join is exactly the disjunction of the
+inputs’ respective bit patterns and prove a lemma about the Invariant relation
+instead. This can be visualised as follows. In each column, the meet is a •
+whenever either of the inputs is.
+◦◦••◦
+∨ •◦◦••
+•◦•••
+The join is of particular importance because it appears when we convert
+an ‘opened’ view of a term into its co-de Bruijn counterpart. As we mentioned
+earlier, co-de Bruijn terms in an arbitrary scope are represented by the pairing of
+a term indexed by its precise support with a thinning embedding this support
+back into the wider scope.
+When working with such a representation, it is
+convenient to have access to an ‘opened’ view where the outer thinning has
+been pushed inside therefore exposing the term’s top-level constructor, ready
+for case-analysis.
+The following diagram shows the correspondence between an ‘opened’ ap-
+plication node using the view (the diamond ‘$’ node) with two subterms both
+living in the outer scope and its co-de Bruijn form (the circular ‘$’ node) with
+an outer thinning selecting the term support.
+$
+t1
+t2
+◦◦••◦
+•◦◦••
+$
+t1
+t2
+•◦•••
+◦••◦
+•◦••
+The outer thinning of the co-de Bruijn term is obtained precisely by com-
+puting the join of the respective outer thinnings of the ‘opened’ application’s
+function and argument.
+These explicit bit manipulations will be preserved during compilation and
+thus deliver more efficient code.
+21
+
+5.5
+Compiled Code
+The following code block shows the JavaScript code that is produced when
+compiling the view function. We chose to use the JavaScript backend rather
+than e.g. the ChezScheme one because it produces fairly readable code. We
+have modified the backend to also write comments reminding the reader of the
+type of the function being defined and the data constructors the natural number
+tags correspond to. These changes are now available to all in Idris 2’s current
+development version.
+The only manual modifications we have performed are the inlining of a func-
+tion corresponding to a case block, renaming variables and property names to
+make them human-readable, introducing the $tail definitions to make lines
+shorter, and slightly changing the layout.
+/* Thin.Smart.view : (th : Th sx sy) -> View th */
+function Thin_Smart_view($th) {
+switch($th.bigEnd) {
+case 0n: return {h: 0 /* Done */};
+default: {
+const $predBE = ($th.bigEnd-1n);
+const $test = choose(notEq(($th.encoding&1n), 0n)));
+switch($test.tag) {
+case 0: /* Left */ {
+const $tail = $th.encoding>>1n;
+return { tag: 1 /* Keep */
+, val: {bigEnd: $predBE, encoding: $tail}}; }
+case 1: /* Right */ {
+const $tail = $th.encoding>>1n;
+return { tag: 2 /* Drop */
+, val: {bigEnd: $predBE, encoding: $tail}}; }
+}}}}
+Readers can see that the compilation process has erased all of the indices
+and the proofs showing that the invariant tying the efficient runtime represen-
+tation to the high-level specification is maintained. A thinning is represented
+at runtime by a JavaScript object with two properties corresponding to Th’s
+runtime relevant fields: bigEnd and encoding. Both are storing a JavaScript
+bigInt (one corresponding to the Nat, the other to the Integer). For instance
+the thinning [01101] would be at runtime { bigEnd: 5n, encoding: 13n }.
+The view proceeds in two steps. First if the bigEnd is 0n then we know the
+thinning is empty and can immediately return the Done constructor. Otherwise
+we know the thinning to be non-empty and so we can compute the big end of its
+tail ($predBE) by subtracting one to the non-zero bigEnd. We can then inspect
+the bit at position 0 to decide whether to return a Keep or a Drop constructor.
+This is performed by using a bit mask to 0-out all the other bits ($th.bigEnd&1n)
+and checking whether the result is zero. If it is not equal to 0 then we emit
+22
+
+Keep and compute the $tail of the thinning by shifting the original encoding
+to drop the 0th bit. Otherwise we emit Drop and compute the same tail.
+By running view on this [01101] thinning, we would get back (Keep [0110]),
+that is to say { tag: 1, val: { bigEnd: 4n, encoding: 6n } }.
+Thanks to Idris 2’s implementation of Quantitative Type Theory we have
+managed to manufacture a high level representation that can be manipulated
+like a classic inductive family using smart constructors and views without giving
+up an inch of control on its runtime representation.
+The remaining issues such as the fact that we form the view’s constructors
+only to immediately take them apart thus creating needless allocations can be
+tackled by reusing Wadler’s analysis (section 12 of [Wad87]).
+6
+Conclusion
+We have seen that inductive families provide programmers with ways to root out
+bugs by enforcing strong invariants. Unfortunately these families can get in the
+way of producing performant code despite existing optimisation passes erasing
+redundant or runtime irrelevant data. This tension has led us to take advantage
+of Quantitative Type Theory in order to design a library combining the best of
+both worlds: the strong invariants and ease of use of inductive families together
+with the runtime performance of explicit bit manipulations.
+6.1
+Related Work
+For historical and ergonomic reasons, idiomatic code in Coq tends to center
+programs written in a subset of the language quite close to OCaml and then
+prove properties about these programs in the runtime irrelevant Prop fragment.
+This can lead to awkward encodings when the unrefined inputs force the user
+to consider cases which ought to be impossible. Common coping strategies in-
+volve relaxing the types to insert a modicum of partiality e.g. returning an
+option type or taking an additional input to be used as the default return value.
+This approach completely misses the point of type-driven development.
+We
+benefit a lot from having as much information as possible available during in-
+teractive editing.
+This information not only helps tremendously getting the
+definitions right by ensuring we always maintain vital invariants thus making
+invalid states unrepresentable, it also gives programmers access to type-driven
+tools and automation. Thankfully libraries such as Equations [Soz10, SM19]
+can help users write more dependently typed programs, by taking care of the
+complex encoding required in Coq. A view-based approach similar to ours but
+using Prop instead of the zero quantity ought to be possible. We expect that
+the views encoded this way in Coq will have an even worse computational be-
+haviour given that Equations uses a sophisticated elaboration process to encode
+dependent pattern-matching into Gallina. However Coq does benefit from good
+automation support for unfolding lemmas, inversion principles, and rewriting
+23
+
+by equalities which may compensate for the awkwardness introduced by the
+encoding.
+Prior work on erasure [Tej20] has the advantage of offering a fully automated
+analysis of the code. The main inconvenience is that users cannot state explic-
+itly that a piece of data ought to be runtime irrelevant and so they may end
+up inadvertently using it which would prevent its erasure. Quantitative Type
+Theory allows us users to explicitly choose what is and is not runtime relevant,
+with the quantity checker keeping us true to our word. This should ensure that
+the resulting program has a much more predictable complexity.
+A somewhat related idea was explored by Brady, McKinna, and Hammond
+in the context of circuit design [BMH07]. In their verification work they index
+an efficient representation (natural numbers as a list of bits) by its meaning
+as a unary natural number. All the operations are correct by construction as
+witnessed by the use of their unary counterparts acting as type-level specifica-
+tions. In the end their algorithms still process the inductive family instead of
+working directly with binary numbers. This makes sense in their setting where
+they construct circuits and so are explicitly manipulating wires carrying bits.
+By contrast, in our motivating example we really want to get down to actual
+(unbounded) integers rather than linked lists of bits.
+6.2
+Limitations and Future Work
+Overall we found this case study using Idris 2, a state of the art language based
+on Quantitative Type Theory, very encouraging. The language implementation
+is still experimental (see for instance appendix B for some of the bugs we found)
+but none of the issues are intrinsic limitations. We hope to be able to push
+this line of work further, tackling the following limitations and exploring more
+advanced use cases.
+6.2.1
+Limitations
+Unfortunately it is only propositionally true that (view (keep th x)) computes
+to (Keep th x) (and similarly for done/Done and drop/Drop). This means that
+users may need to manually deploy these lemmas when proving the properties
+of functions defined by pattern matching on the result of calling the view func-
+tion. This annoyance would disappear if we had the ability to extend Idris 2’s
+reduction rules with user-proven equations as implemented in Agda and formally
+studied by Cockx, Tabareau, and Winterhalter [CTW21].
+In this paper’s case study, we were able to design the core Invariant relation
+making the invariants explicit in such a way that it would be provably proof
+irrelevant. This may not always be possible given the type theory currently im-
+plemented by Idris 2. Adding support for a proof-irrelevant sort of propositions
+(see e.g. Altenkirch, McBride, and Swierstra’s work [AMS07]) could solve this
+issue once and for all.
+The Idris 2 standard library thankfully gave us access to a polished pure
+interface to explicitly manipulate an integer’s bits. However these built-in oper-
+24
+
+ations came with no built-in properties whatsoever. And so we had to postulate
+a (minimal) set of axioms (see appendix A) and prove a lot of useful corollar-
+ies ourselves. There is even less support for other low-level operations such as
+reading from a read-only array, or manipulating pointers.
+We also found the use of runtime irrelevance (the 0 quantity) sometimes
+somewhat frustrating.
+Pattern-matching on a runtime irrelevant value in a
+runtime relevant context is currently only possible if it is manifest for the
+compiler that the value could only arise using one of the family’s construc-
+tors.
+In non-trivial cases this is unfortunately only merely provable rather
+than self-evident. Consequently we are forced to jump through hoops to ap-
+pease the quantity checker, and end up defining complex inversion lemmas to
+bypass these limitations. This could be solved by a mix of improvements to
+the typechecker and meta-programming using prior ideas on automating inver-
+sion [CT95, McB96, Mon10].
+6.2.2
+Future work
+We are planning to explore more memory-mapped representations equipped
+with a high level interface.
+We already have experimental results demonstrating that we can use a read-
+only array as a runtime representation of a binary search tree. Search can be
+implemented as a proven-correct high level decision procedure that is seem-
+ingly recursively exploring the ”tree”. At runtime however, this will effectively
+execute like a classic search by dichotomy over the array.
+More generally, we expect that a lot of the work on programming on serialised
+data done in LoCal [VKR+19] thanks to specific support from the compiler can
+be done as-is in a QTT-based programming language.
+Indeed, QTT’s type
+system is powerful enough that tracking these invariants can be done purely in
+library code.
+In the short term, we would like to design a small embedded domain specific
+language giving users the ability to more easily build and take apart products
+and sums efficiently represented in the style we presented here. Staging would
+help here to ensure that the use of the eDSL comes at no runtime cost. There
+are plans to add type-enforced staging to Idris 2, thus really making it the ideal
+host language for our project.
+Our long term plan is to go beyond read-only data and look at imperative
+programs proven correct using separation logic and see how much of this after-
+the-facts reasoning can be brought back into the types to enable a high-level
+correct-by-construction programming style that behaves the same at runtime.
+Acknowledgements
+We are grateful to Conor McBride for discussions per-
+taining to the fine details of the unsafe encoding used in TypOS, as well as James
+McKinna, Fredrik Nordvall Forsberg, Ohad Kammar, and Jacques Carette for
+providing helpful comments and suggestions on early versions of this paper.
+25
+
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+Conor McBride.
+I got plenty o’ nuttin’.
+In Sam Lindley, Conor
+McBride, Philip W. Trinder, and Donald Sannella, editors, A List of
+Successes That Can Change the World - Essays Dedicated to Philip
+Wadler on the Occasion of His 60th Birthday, volume 9600 of Lec-
+ture Notes in Computer Science, pages 207–233. Springer, 2016.
+[McB18]
+Conor McBride.
+Everybody’s got to be somewhere.
+In Robert
+Atkey and Sam Lindley, editors, Proceedings of the 7th Workshop on
+Mathematically Structured Functional Programming, MSFP@FSCD
+2018, Oxford, UK, 8th July 2018, volume 275 of EPTCS, pages 53–
+69, 2018.
+[MEL+21] Krzysztof Maziarz, Tom Ellis, Alan Lawrence, Andrew W. Fitzgib-
+bon, and Simon Peyton Jones. Hashing modulo alpha-equivalence.
+In Stephen N. Freund and Eran Yahav, editors, PLDI ’21: 42nd
+ACM SIGPLAN International Conference on Programming Lan-
+guage Design and Implementation, Virtual Event, Canada, June
+20-25, 2021, pages 960–973. ACM, 2021.
+[MM04]
+Conor McBride and James McKinna. The view from the left. J.
+Funct. Program., 14(1):69–111, 2004.
+[Mon10]
+Jean-Fran¸cois Monin. Proof Trick: Small Inversions. In Yves Bertot,
+editor, Second Coq Workshop, Edinburgh, United Kingdom, July
+2010. Yves Bertot.
+27
+
+[SM19]
+Matthieu Sozeau and Cyprien Mangin. Equations reloaded: high-
+level dependently-typed functional programming and proving in coq.
+Proc. ACM Program. Lang., 3(ICFP):86:1–86:29, 2019.
+[Soz10]
+Matthieu Sozeau. Equations: A dependent pattern-matching com-
+piler. In Matt Kaufmann and Lawrence C. Paulson, editors, Inter-
+active Theorem Proving, First International Conference, ITP 2010,
+Edinburgh, UK, July 11-14, 2010. Proceedings, volume 6172 of Lec-
+ture Notes in Computer Science, pages 419–434. Springer, 2010.
+[Tej20]
+Mat´uˇs Tejiˇsˇc´ak.
+A dependently typed calculus with pattern
+matching and erasure inference.
+Proc. ACM Program. Lang.,
+4(ICFP):91:1–91:29, 2020.
+[VKR+19] Michael Vollmer, Chaitanya Koparkar, Mike Rainey, Laith Sakka,
+Milind Kulkarni, and Ryan R. Newton. Local: a language for pro-
+grams operating on serialized data. In Kathryn S. McKinley and
+Kathleen Fisher, editors, Proceedings of the 40th ACM SIGPLAN
+Conference on Programming Language Design and Implementation,
+PLDI 2019, Phoenix, AZ, USA, June 22-26, 2019, pages 48–62.
+ACM, 2019.
+[Wad87]
+Philip Wadler. Views: A way for pattern matching to cohabit with
+data abstraction. In Conference Record of the Fourteenth Annual
+ACM Symposium on Principles of Programming Languages, Mu-
+nich, Germany, January 21-23, 1987, pages 307–313. ACM Press,
+1987.
+[WB89]
+Philip Wadler and Stephen Blott. How to make ad-hoc polymor-
+phism less ad-hoc. In Conference Record of the Sixteenth Annual
+ACM Symposium on Principles of Programming Languages, Austin,
+Texas, USA, January 11-13, 1989, pages 60–76. ACM Press, 1989.
+A
+Postulated lemmas for the Bits interface
+It is often more convenient to reason about integers in terms of their bits. We
+define the notion of bitwise equality as the pointwise equality according to the
+testBit.
+(˜˜˜) : Integer -> Integer -> Type
+bs ˜˜˜ cs = (i : Nat) -> testBit bs i === testBit cs i
+Our first postulate is a sort of extensionality principle stating that bitwise
+equality implies propositional equality.
+extensionally : {bs, cs : Integer} -> bs ˜˜˜ cs -> bs === cs
+28
+
+This gives us a powerful reasoning principle once combined with axioms
+explaining the behaviour of various primitives at the bit level.
+This is why
+almost all of the remaining axioms are expressed in terms of testBit calls.
+A.1
+Logical operations
+Our first batch of axioms relates logical operations on integers to their boolean
+counterparts. This is essentially stating that these operations are bitwise.
+testBitAnd : (bs, cs : Integer) -> (i : Nat) ->
+testBit (bs .&. cs) i === (testBit bs i && testBit cs i)
+testBitOr : (bs, cs : Integer) -> (i : Nat) ->
+testBit (bs .|. cs) i === (testBit bs i || testBit cs i)
+testBitComplement : (bs : Integer) -> (i : Nat) ->
+testBit (complement bs) i === not (testBit bs i)
+Together with the extensionality principle mentioned above this already al-
+lows us to prove for instance that the binary operators are commutative and
+associative, that the de Morgan laws hold, or that conjunction distributes over
+disjunction.
+A.2
+Bit Shifting
+The second set of axiom describes the action of left and right shifting on bit
+patterns.
+A right shift of size k will drop the k least significant bits; consequently
+testing the bit i on the right-shifted integer amounts to testing the bit (k + i)
+on the original integer.
+testBitShiftR : (bs : Integer) -> (k : Nat) ->
+(i : Nat) -> testBit (bs ‘shiftR‘ k) i === testBit bs (k + i)
+A left shift will add k new least significant bits initialised at 0; consequently
+testing a bit i on the left-shifted integer will either return False if i is strictly
+less than k, or the bit at position (i - k) in the original integer.
+For simplicity we state these results without mentioning the ‘strictly less
+than’ relation, by considering on the one hand the effect of a non-zero left shift,
+and on the other the fact that a left-shift by 0 bits is the identity function.
+testBit0ShiftL : (bs : Integer) -> (k : Nat) ->
+testBit (bs ‘shiftL‘ S k) Z === False
+testBitSShiftL : (bs : Integer) -> (k : Nat) -> (i : Nat) ->
+testBit (bs ‘shiftL‘ S k) (S i) === testBit (bs ‘shiftL‘ k) i
+29
+
+shiftL0 : (bs : Integer) -> (bs ‘shiftL‘ 0) === bs
+A.3
+Bit testing
+The last set of axioms specifies what happens when a bit is set.
+Testing a bit other than the one that was set amounts to testing it on the
+original integer.
+testSetBitOther : (bs : Integer) -> (i, j : Nat) -> Not (i === j) ->
+testBit (setBit bs i) j === testBit bs j
+Finally, we have an axiom stating that the integer (bit i) (i.e. 2i) is non-
+zero.
+bitNonZero : (i : Nat) -> (bit i == 0) === False
+B
+Current Limitations of Idris 2
+This challenge, suggested by Jacques Carette, highlights some of the current
+limitations of Idris 2.
+B.1
+Problem statement
+The goal is to use the Vect type defined in section 3.3 and define a view that
+un-does vector-append. This is a classic exercise in dependently-typed program-
+ming, the interesting question being whether we can implement the function just
+as seamlessly with our encoding.
+Vector append can easily be defined by induction over the first vector.
+(++) : Vect m a -> Vect n a -> Vect (m + n) a
+xs@_ ++ ys with (view xs)
+_ | [] = ys
+_ | hd :: tl = hd :: (tl ++ ys)
+If the first vector is empty we can readily return the second vector. If it
+is cons-headed, we can return the head and compute the tail by performing a
+recursive call.
+Equipped with this definition, we can declare the view type which we call
+SplitAt by analogy with its weakly typed equivalent processing lists. It states
+that a vector xs of length p can be split at m if p happens to be (m + n) and xs
+happens to be (pref ++ suff) where pref and suff’s respective lengths are m
+and n.
+30
+
+data SplitAt : (m : Nat) -> (xs : Vect p a) -> Type where
+MkSplitAt : (pref : Vect m a) -> (suff : Vect n a) ->
+SplitAt m (pref ++ suff)
+The challenge is to define the function proving that a vector of size (m + n)
+can be split at m.
+B.2
+Failing attempts
+The proof will necessarily go by induction on m, followed by a case analysis on
+the input vector and a recursive call in the non-zero case.
+Our first failing attempt successfully splits the natural number, calls the view
+on the vector xs to take it apart but then fails when performing the recursive
+call to splitAt.
+failing "tl is not accessible in this context"
+splitAt : (m : Nat) -> (xs : Vect (m + n) a) -> SplitAt m xs
+splitAt 0 xs = MkSplitAt [] xs
+splitAt (S m) xs@_ with (view xs)
+_ | hd :: tl@_ with (splitAt m tl)
+_ | res = ?a
+This reveals an issue in Idris 2’s handling of the interplay between @-patterns
+and quantities: the compiler arbitrarily decided to make the alias tl runtime
+irrelevant only to then complain that tl is not accessible when we want to
+perform the recursive call (splitAt m tl)!
+In order to work around this limitation, we decided to let go of @-patterns
+and write the fully explicit clause ourselves, using dotted patterns to mark the
+forced expressions.
+failing "Can’t match on ?postpone [no locals in scope] (User dotted)"
+splitAt : (m : Nat) -> (xs : Vect (m + n) a) -> SplitAt m xs
+splitAt 0 xs = MkSplitAt [] xs
+splitAt (S m) xs@_ with (view xs)
+_ | hd :: tl with (splitAt m tl)
+splitAt (S m) .(hd :: (pref ++ suff))
+| hd :: .(pref ++ suff)
+| MkSplitAt pref suff = ?a
+The left-hand side now typechecks but the case tree builder fails with a
+perplexing error. This reveals a bug in Idris 2’s implementation of elaboration of
+pattern-matching functions to case trees. Instead of ignoring dotted expressions
+when building the case tree (these expressions are forced and so the variables
+they mention will have necessarily been bound in another pattern), it attempts
+to use them to drive the case-splitting strategy. This is a well-studied problem
+and should be fixable by referring to Cockx and Abel’s work [CA20].
+31
+
+B.3
+Working Around Idris 2’s Limitations
+This leads us to our working solution. Somewhat paradoxically, working around
+these Idris 2 bugs led us to a more principled solution whereby the pattern-
+matching step needed to adjust the result returned by the recursive call is ab-
+stracted away in an auxiliary function whose type clarifies what is happening.
+From an m split on xs, we can easily compute an (S m) split on (x :: xs) by
+cons-ing x on the prefix.
+(::) : (x : a) -> SplitAt m xs -> SplitAt (S m) (x :: xs)
+x :: MkSplitAt pref@(MkVect _ Refl) suff
+= MkSplitAt (x :: pref) suff
+In this auxiliary function, xs is clearly runtime irrelevant and so the case-
+splitter will not attempt to inspect it, thus generating the correct case tree.
+We are forced to match further on pref (in particular by making the equality
+proof Refl) so that just enough computation happens at the type level for the
+typechecker to see that things do line up. A proof irrelevant type of propositional
+equality would have helped us here.
+We can put all of these pieces together and finally get our splitAt view.
+splitAt : (m : Nat) -> (xs : Vect (m + n) a) -> SplitAt m xs
+splitAt 0 xs = MkSplitAt [] xs
+splitAt (S m) xs@_ with (view xs)
+_ | hd :: tl = hd :: splitAt m tl
+We do want to reiterate that these limitations are not intrinsic limitations of
+the approach, there are just flaws in the current experimental implementation
+of the Idris 2 language and can and should be remedied.
+32
+
diff --git a/D9E0T4oBgHgl3EQfQgCE/content/tmp_files/load_file.txt b/D9E0T4oBgHgl3EQfQgCE/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..55bb28755930567c8414bf8c5362b08c77036998
--- /dev/null
+++ b/D9E0T4oBgHgl3EQfQgCE/content/tmp_files/load_file.txt
@@ -0,0 +1,687 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf,len=686
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='02194v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='PL]  5 Jan 2023  Builtin Types viewed as Inductive Families  Guillaume Allais  January 6, 2023  Abstract  State of the art optimisation passes for dependently typed languages  can help erase the redundant information typical of invariant-rich data  structures and programs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' These automated processes do not dramatically  change the structure of the data, even though more efficient representa-  tions could be available.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Using Quantitative Type Theory, we demonstrate how to define an  invariant-rich, typechecking time data structure packing an efficient run-  time representation together with runtime irrelevant invariants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The com-  piler can then aggressively erase all such invariants during compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Unlike other approaches, the complexity of the resulting representation  is entirely predictable, we do not require both representations to have the  same structure, and yet we are able to seamlessly program as if we were  using the high-level structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  1  Introduction  Dependently typed languages have empowered users to precisely describe their  domain of discourse by using inductive families [Dyb94].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Programmers can bake  crucial invariants directly into their definitions thus refining both their func-  tions’ inputs and outputs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The constrained inputs allow them to only consider  the relevant cases during pattern matching, while the refined outputs guaran-  tee that client code can safely rely on the invariants being maintained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This  programming style is dubbed ‘correct by construction’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  However, relying on inductive families can have a non-negligible runtime  cost if the host language is compiling them na¨ıvely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' And even state of the art  optimisation passes for dependently typed languages cannot make miracles: if  the source code is not efficient, the executable will not be either.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A state of the art compiler will for instance successfully compile length-  indexed lists to mere lists thus reducing the space complexity from quadratic  to linear in the size of the list.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' But, confronted with a list of booleans whose  length is statically known to be less than 64, it will fail to pack it into a single  machine word thus spending linear space when constant would have sufficed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In section 2, we will look at an optimisation example that highlights both  the strengths and the limitations of the current state of the art when it comes to  removing the runtime overheads potentially incurred by using inductive families.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  1  In section 3 we will give a quick introduction to Quantitative Type Theory,  the expressive language that grants programmers the ability to have both strong  invariants and, reliably, a very efficient runtime representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In section 4 we will look at an inductive family that we use in a performance-  critical way in the TypOS project [AAM+22] and whose compilation suffers  from the limitations highlighted in section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Our current and unsatisfactory  approach is to rely on the safe and convenient inductive family when experi-  menting in Agda and then replace it with an unsafe but vastly more efficient  representation in our actual Haskell implementation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Finally in section 5, we will study the actual implementation of our efficient  and invariant-rich solution implemented in Idris 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will also demonstrate  that we can recover almost all the conveniences of programming with inductive  families thanks to smart constructors and views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  2  An Optimisation Example  The prototypical examples of the na¨ıve compilation of inductive families being  inefficient are probably the types of vectors (Vect) and finite numbers (Fin).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Their interplay is demonstrated by the lookup function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Let us study this  example and how successive optimisation passes can, in this instance, get rid of  the overhead introduced by using indexed families over plain data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A vector is a length-indexed list.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The type Vect is parameterised by the  type of values it stores and indexed over a natural number corresponding to its  length.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' More concretely, its Nil constructor builds an empty vector of size Z  (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' zero), and its (::) (pronounced ‘cons’) constructor combines a value of  type a (the head) and a subvector of size n (the tail) to build a vector of size (S  n) (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' successor of n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  data Vect : Nat -> Type -> Type where  Nil : Vect Z a  (::) : a -> Vect n a -> Vect (S n) a  The size n is not explicitly bound in the type of (::).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Idris 2, this means  that it is automatically generalised over in a prenex manner reminiscent of the  handling of free type variables in languages in the ML family.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This makes it  an implicit argument of the constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Consequently, given that Nat is a  type of unary natural numbers, a na¨ıve runtime representation of a (Vect n a)  would have a size quadratic in n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A smarter representation with perfect sharing  would still represent quite an overhead as observed by Brady, McBride, and  McKinna [BMM03].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A finite number is a number known to be strictly smaller than a given natural  number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The type Fin is indexed by said bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Its Z constructor models 0 and  is bound by any non-zero bound, and its S constructor takes a number bound  by n and returns its successor, bound by (1 + n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A na¨ıve compilation would  here also lead to a runtime representation suffering from a quadratic blowup.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  2  data Fin : Nat -> Type where  Z : Fin (S n)  S : Fin n -> Fin (S n)  This leads us to the definition of the lookup function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Provided a vector of  size n and a finite number k bound by this same n, we can define a total function  looking up the value stored at position k in the vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is guaranteed to return  a value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Note that we do not need to consider the case of the empty vector in the  pattern matching clauses as all of the return types of the Fin constructors force  the index to be non-zero and, because the vector and the finite number talk  about the same n, having an empty vector would automatically imply having a  value of type (Fin 0) which is self-evidently impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  lookup : Vect n a -> Fin n -> a  lookup (x :: _) Z = x  lookup (_ :: xs) (S k) = lookup xs k  Thanks to our indexed family, we have gained the ability to define a function  that cannot possibly fail, as well as the ability to only talk about the pattern  matching clauses that make sense.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This seemed to be at the cost of efficiency but  luckily for us there has already been extensive work on erasure to automatically  detect redundant data [BMM03] or data that will not be used at runtime [Tej20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Optimising Vect, Fin, and lookup  An analysis in the style of Brady, McBride, and McKinna’s [BMM03] can solve  the quadratic blowup highlighted above by observing that the natural number  a vector is indexed by is entirely determined by the spine of the vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In  particular, the length of the tail does not need to be stored as part of the  constructor: it can be reconstructed as the predecessor of the length of the  overall vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' As a consequence, a vector can be adequately represented at  runtime by a pair of a natural number and a list.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Similarly a bounded number  can be adequately represented by a pair of natural numbers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Putting all of this  together and remembering that the vector and the finite number share the same  n, lookup can be compiled to a function taking two natural numbers and a list.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In Idris 2 we would write the optimised lookup as follows (we use the partial  keyword because this transformed version is not total at that type).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  partial  lookup : (n : Nat) -> List a -> Nat -> a  lookup (S n) (x :: _) Z = x  lookup (S n) (_ :: xs) (S k) = lookup n xs k  We can see in the second clause that the recursive call is performed on the tail  of the list (formerly vector) and so the first argument to lookup corresponding  to the vector’s size is decreased by one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The invariant, despite not being explicit  anymore, is maintained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  3  A Tejiˇsˇc´ak-style analysis [Tej20] can additionally notice that the lookup func-  tion never makes use of the bound’s value and drop it entirely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This leads to  the lookup function on vectors being compiled to its partial-looking counterpart  acting on lists.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  partial  lookup : List a -> Nat -> a  lookup (x :: _) Z = x  lookup (_ :: xs) (S k) = lookup xs k  Even though this is in our opinion a pretty compelling example of erasing  away the apparent complexity introduced by inductive families, this approach  has two drawbacks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Firstly, it relies on the fact that the compiler can and will automatically  perform these optimisations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' But nothing in the type system prevents users from  inadvertently using a value they thought would get erased, thus preventing the  Tejiˇsˇc´ak-style optimisation from firing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In performance-critical settings, users  may rather want to state their intent explicitly and be kept to their word by  the compiler in exchange for predictable and guaranteed optimisations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Secondly, this approach is intrinsically limited to transformations that pre-  serve the type’s overall structure: the runtime data structures are simpler but  very similar still.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We cannot expect much better than that.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is so far unre-  alistic to expect e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' a change of representation to use a balanced binary tree  instead of a list in order to get logarithmic lookups rather than linear ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  No Magic Solution  Even if we are able to obtain a more compact representation of the inductive  family at runtime through enough erasure, this does not guarantee runtime  efficiency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' As the Coq manual [CDT22] reminds its users, extraction does not  magically optimise away a user-defined quadratic multiplication algorithm when  extracting unary natural numbers to an efficient machine representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In  a pragmatic move, Coq, Agda, and Idris 2 all have ad-hoc rules to replace  convenient but inefficiently implemented numeric functions with asymptotically  faster counterparts in the target language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  However this approach is not scalable: if we may be willing to extend our  trusted core to a high quality library for unbounded integers, we do not want to  replace our code only proven correct thanks to complex invariants with a wildly  different untrusted counterpart purely for efficiency reasons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In this paper we use Quantitative Type Theory [McB16, Atk18] as imple-  mented in Idris 2 [Bra21] to bridge the gap between an invariant-rich but in-  efficient representation based on an inductive family and an unsafe but effi-  cient implementation using low-level primitives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Inductive families allow us to  view [Wad87, MM04] the runtime relevant information encoded in the low-level  and efficient representation as an information-rich compile time data structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Moreover the quantity annotations guarantee that this additional information  4  will be erased away during compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  3  Some Key Features of Idris 2  Idris 2 implements Quantitative Type Theory, a Martin-L¨of type theory enriched  with a semiring of quantities classifying the ways in which values may be used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In a type, each binder is annotated with the quantity by which its argument  must abide.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Quantities  A value may be runtime irrelevant, linear, or unrestricted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Runtime irrelevant values (0 quantity) cannot possibly influence control flow  as they will be erased entirely during compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This forces the language  to impose strong restrictions on pattern-matching over these values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Typical  examples are types like the a parameter in (List a), or indices like the natural  number n in (Vect n a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' These are guaranteed to be erased at compile time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The advantage over a Tejiˇsˇc´ak-style analysis is that users can state their intent  that an argument ought to be runtime irrelevant and the language will insist  that it needs to be convinced it indeed is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Linear values (1 quantity) have to be used exactly once.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Typical examples  include the %World token used by Idris 2 to implement the IO monad `a la Haskell,  or file handles that cannot be discarded without first explicitly closing the file.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  At runtime these values can be updated destructively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will not use linearity  in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Last, unrestricted values (denoted by no quantity annotation) can flow into  any position, be duplicated or thrown away.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' They are the usual immutable  values of functional programming.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The most basic of examples mobilising both the runtime irrelevance and  unrestricted quantities is the identity function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  id : {0 a : Type} -> (x : a) -> a  id x = x  Its type starts with a binder using curly braces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This means it introduces  an implicit variable that does not need to be filled in by the user at call sites  and will be reconstructed by unification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The variable it introduces is named  a and has type Type.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It has the 0 quantity annotation which means that this  argument is runtime irrelevant and so will be erased during compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The second binder uses parentheses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It introduces an explicit variable whose  name is x and whose type is the type a that was just bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It has no quantity  annotation which means it will be an unrestricted variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Finally the return type is the type a bound earlier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is, as expected, a  polymorphic function from a to a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is implemented using a single clause that  binds x on the left-hand side and immediately returns it on the right-hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5  If we were to try to annotate the binder for x with a 0 quantity to make  it runtime irrelevant then Idris 2 would rightfully reject the definition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The  following failing block shows part of the error message complaining that x  cannot be used at an unrestricted quantity on the right-hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  failing "x is not accessible in this context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='"  id : {0 a : Type} -> (0 x : a) -> a  id x = x  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Proof Search  In Idris 2, Haskell-style ad-hoc polymorphism [WB89] is superseded by a more  general proof search mechanism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Instead of having blessed notions of type  classes, instances and constraints, the domain of any dependent function type  can be marked as auto.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This signals to the compiler that the corresponding  argument will be an implicit argument and that it should not be reconstructed  by unification alone but rather by proof search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The search algorithm will use  the appropriate user-declared hints as well as the local variables in scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  By default, a datatype’s constructors are always added to the database of  hints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' And so the following declaration brings into scope both an indexed family  So of proofs that a given boolean is True, and a unique constructor Oh that is  automatically added as a hint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  data So : Bool -> Type where  Oh : So True  As a consequence, we can for instance define a record type specifying what  it means for n to be an even number by storing its half together with a proof  that is both runtime irrelevant and filled in by proof search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Because (2 * 3 ==  6) computes to True, Idris 2 is able to fill-in the missing proof in the definition  of even6 using the Oh hint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  record Even (n : Nat) where  constructor MkEven  half : Nat  {auto 0 prf : So (2 * half == n)}  even6 : Even 6  even6 = MkEven { half = 3 }  We will use both So and the auto mechanism in section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3  Application: Vect, as List  We can use the features of Quantitative Type Theory to give an implementa-  tion of Vect that is guaranteed to erase to a List at runtime independently of  the optimisation passes implemented by the compiler.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The advantage over the  optimisation passes described in section 2 is that the user has control over the  6  runtime representation and does not need to rely on these optimisations being  deployed by the compiler.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The core idea is to make the slogan ‘a vector is a length-indexed list’ a  reality by defining a record packing together the encoding as a list and a proof  its length is equal to the expected Nat index.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This proof is marked as runtime  irrelevant to ensure that the list is the only thing remaining after compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  record Vect (n : Nat) (a : Type) where  constructor MkVect  encoding : List a  0 valid : length encoding === n  Smart constructors  Now that we have defined vectors, we can recover the  usual building blocks for vectors by defining smart constructors, that is to say  functions Nil and (::) that act as replacements for the inductive family’s data  constructors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Nil : Vect Z a  Nil = MkVect [] Refl  The smart constructor Nil returns an empty vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is, unsurprisingly,  encoded as the empty list ([]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Because (length []) statically computes to Z,  the proof that the encoding is valid can be discharged by reflexivity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  (::) : a -> Vect n a -> Vect (S n) a  x :: MkVect xs eq = MkVect (x :: xs) (cong S eq)  Using (::) we can combine a head and a tail of size n to obtain a vector of  size (S n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The encoding is obtained by consing the head in front of the tail’s  encoding and the proof this is valid (cong S eq) uses the fact that propositional  equality is a congruence and that (length (x :: xs)) computes to (S (length  xs)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  View  Now that we know how to build vectors, we demonstrate that we can  also take them apart using a view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A view for a type T , in the sense of Wadler [Wad87], and as refined by  McBride and McKinna [MM04], is an inductive family V indexed by T together  with a total function mapping every element t of T to a value of type (V t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This  simple gadget provides a powerful, user-extensible, generalisation of pattern-  matching.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Patterns are defined inductively as either a pattern variable, a forced  term (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' an arbitrary expression that is determined by a constraint arising  from another pattern), or a data constructor fully applied to subpatterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In  contrast, the return indices of an inductive family’s constructors can be arbitrary  expressions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In the case that interests us, the view allows us to emulate ‘matching’ on  which of the two smart constructors Nil or (::) was used to build the vector  being taken apart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  7  data View : Vect n a -> Type where  Nil : View Nil  (::) : (x : a) -> (xs : Vect n a) -> View (x :: xs)  The inductive family View is indexed by a vector and has two constructors  corresponding to the two smart constructors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We use Idris 2’s overloading capa-  bilities to give each of the View’s constructors the name of the smart constructor  it corresponds to.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' By pattern-matching on a value of type (View xs), we will be  able to break xs into its constitutive parts and either observe it is equal to Nil  or recover its head and its tail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  view : (xs : Vect n a) -> View xs  view (MkVect [] Refl) = Nil  view (MkVect (x :: xs) Refl) = x :: MkVect xs Refl  The function view demonstrates that we can always tell which constructor  was used by inspecting the encoding list.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it is empty, the vector was built  using the Nil smart constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it is not then we got our hands on the  head and the tail of the encoding and (modulo some re-wrapping of the tail)  they are effectively the head and the tail that were combined using the smart  constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Application: map  We can then use these constructs to implement the function map on vectors  without ever having to explicitly manipulate the encoding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The maximally  sugared version of map is as follows:  map : (a -> b) -> Vect n a -> Vect n b  map f xs@_ with (view xs)  _ | [] = []  _ | hd :: tl = f hd :: map f tl  On the left-hand side the view lets us seamlessly pattern-match on the input  vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Using the with keyword we have locally modified the function defini-  tion so that it takes an extra argument, here the result of the intermediate  computation (view xs).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Correspondingly, we have two clauses matching on this  extra argument;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' the symbol | separates the original left-hand side (here elided  using _ because it is exactly the same as in the parent clause) from the addi-  tional pattern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This pattern can either have the shape [] or (hd :: tl) and,  correspondingly, we learn that xs is either [] or (hd :: tl).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  On the right-hand side the smart constructors let us build the output vec-  tor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Mapping a function over the empty vector yields the empty vector while  mapping over a cons node yields a cons node whose head and tail have been  appropriately modified.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  This sugared version of map is equivalent to the following more explicit one:  8  map : (a -> b) -> Vect n a -> Vect n b  map f xs with (view xs)  map f .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ([]) | [] = []  map f .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (hd :: tl) | hd :: tl = f hd :: map f tl  In the parent clause we have explicitly bound xs instead of merely introduc-  ing an alias for it by writing (xs@ ) and so we will need to be explicit about the  ways in which this pattern is refined in the two with-clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In the with-clauses, we have explicitly repeated the refined version of the  parent clause’s left-hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In particular we have used dotted patterns to  insist that xs is now entirely forced by the match on the result of (view xs).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We have seen that by matching on the result of the (view xs) call, we get to  ‘match’ on xs as if Vect were an inductive type.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is the power of views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Application: lookup  The type (Fin n) can similarly be represented by a single natural number and  a runtime irrelevant proof that it is bound by n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We leave these definitions  out, and invite the curious reader to either attempt to implement them for  themselves or look at the accompanying code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Bringing these definitions together, we can define a lookup function which  is similar to the one defined in section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  lookup : Vect n a -> Fin n -> a  lookup xs@_ k@_ with (view xs) | (view k)  _ | hd :: _ | Z = hd  _ | _ :: tl | S k’ = lookup tl k’  We are seemingly using view at two different types (Vect and Fin respec-  tively) but both occurrences actually refer to separate functions: Idris 2 lets us  overload functions and performs type-directed disambiguation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  For pedagogical purposes, this sugared version of lookup can also be ex-  panded to a more explicit one that demonstrates the views’ power.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  lookup : Vect n a -> Fin n -> a  lookup xs k with (view xs) | (view k)  lookup .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (hd :: tl) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (Z) | hd :: tl | Z = hd  lookup .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (hd :: tl) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (S k’) | hd :: tl | S k’ = lookup tl k’  The main advantage of this definition is that, based on its type alone, we  know that this function is guaranteed to be processing a list and a single natural  number at runtime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This efficient runtime representation does not rely on the  assumption that state of the art optimisation passes will be deployed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We have seen some of Idris 2’s powerful features and how they can be lever-  aged to empower users to control the runtime representation of the inductive  families they manipulate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This simple example only allowed us to reproduce  the performance that could already be achieved by compilers deploying state of  the art optimisation passes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In the following sections, we are going to see how  9  we can use the same core ideas to compile an inductive family to a drastically  different runtime representation while keeping good high-level ergonomics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  4  Thinnings, cooked two ways  We experienced a major limitation of compilation of inductive families during  our ongoing development of TypOS [AAM+22], a domain specific language to  define concurrent typecheckers and elaborators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Core to this project is the defi-  nition of actors manipulating a generic notion of syntax with binding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Internally  the terms of this syntax with binding are based on a co-de Bruijn representa-  tion (an encoding we will explain below) which relies heavily on thinnings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A  thinning (also known as an Order Preserving Embedding [Cha09]) between a  source and a target scope is an order preserving injection of the smaller scope  into the larger one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' They are usually represented using an inductive family.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The omnipresence of thinnings in the co-de Bruijn representation makes their  runtime representation a performance critical matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Let us first remind the reader of the structure of abstract syntax trees in a  named, a de Bruijn, and a co-de Bruijn representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will then discuss two  representations of thinnings: a safe and convenient one as an inductive family,  and an unsafe but efficient encoding as a pair of arbitrary precision integers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Named, de Bruijn, and co-de Bruijn syntaxes  In this section we will use the S combinator (λg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='λf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='λx.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='gx(fx)) as a running  example and represent terms using a syntax tree whose constructor nodes are  circles and variable nodes are squares.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  To depict the S combinator we will  only need λ-abstraction and application (rendered $) nodes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A constructor’s  arguments become its children in the tree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The tree is laid out left-to-right and  a constructor’s arguments are displayed top-to-bottom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Named syntax  The first representation is using explicit names.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Each binder  has an associated name and each variable node carries a name.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A variable refers  to the closest enclosing binder which happens to be using the same name.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λx.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  $  $  g  x  $  f  x  To check whether two terms are structurally equivalent (α-equivalence) po-  tentially requires renaming bound names.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In order to have a simple and cheap  α-equivalence check we can instead opt for a nameless representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  10  De Bruijn syntax  An abstract syntax tree based on de Bruijn indices [dB72]  replaces names with natural numbers counting the number of binders separating  a variable from its binding site.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The S combinator is now written (λ λ λ 2 0 (1 0)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  You can see in the following graphical depiction that λ-abstractions do not  carry a name anymore and that variables are simply pointing to the binder  that introduced them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We have left the squares empty but in practice the  various coloured arrows would be represented by a natural number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' For instance  the dashed magenta one corresponds to 1 because you need to ignore one λ-  abstraction (the orange one) on your way towards the root of the tree before  you reach the corresponding magenta binder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  $  $  $  To check whether a subterm does not mention a given set of variables (a  thickening test, the opposite of a thinning which extends the current scope with  unused variables), you need to traverse the whole term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In order to have a  simple cheap thickening test we can ensure that each subterms knows precisely  what its support is and how it embeds in its parent’s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Co-de Bruijn syntax  In a co-de Bruijn representation [McB18] each subterm  selects exactly the variables that stay in scope for that term, and so a variable  constructor ultimately refers to the only variable still in scope by the time it is  reached.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This representation ensures that we know precisely what the scope of  a given term currently is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In the following graphical rendering, we represent thinnings as lists of full  (•) or empty (◦) discs depending on whether the corresponding variable is either  kept or discarded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' For instance the thinning represented by ◦•• throws the blue  variable away, and keeps both the magenta and orange ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  $  $  $ ••  •••  ◦••  •◦•  •◦  ◦•  •◦  ◦•  11  We can see that in such a representation, each node in the tree stores one  thinning per subterm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This will not be tractable unless we have an efficient  representation of thinnings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  The Performance Challenges of co-de Bruijn  Using the co-de Bruijn approach, a term in an arbitrary context is repre-  sented by the pairing of a term in co-de Bruijn syntax with a thinning from  its support into the wider scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Having such a precise handle on each term’s  support allows us to make operations such as thinning, substitution, unification,  or common sub-expression elimination more efficient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Thinning a term does not require us to traverse it anymore.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Indeed, embed-  ding a term in a wider context will not change its support and so we can simply  compose the two thinnings while keeping the term the same.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Substitution can avoid traversing subterms that will not be changed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Indeed,  it can now easily detect when the substitution’s domain does not intersect with  the subterm’s support.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Unification requires performing thickening tests when we want to solve a  metavariable declared in a given context with a terms seemingly living in a  wider one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We once more do not need to traverse the term to perform this test,  and can simply check whether the outer thinning can be thickened.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Common sub-expression elimination requires us to identify alpha-equivalent  terms potentially living in different contexts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Using a de Bruijn representation,  these can be syntactically different: a variable represented by the natural num-  ber v in Γ would be (1+v) in Γ, σ but (2+v) in Γ, τ, ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A co-de Bruijn represen-  tation, by discarding all the variables not in the support, guarantees that we can  once more use syntactic equality to detect alpha-equivalence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This encoding is  used for instance (albeit unknowingly) by Maziarz, Ellis, Lawrence, Fitzgibbon,  and Peyton-Jones in their ‘Hashing modulo alpha-equivalence’ work [MEL+21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  For all of these reasons we have, as we mentioned earlier, opted for a co-de  Bruijn representation in the implementation of TypOS [AAM+22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  And so it  is crucial for performance that we have a compact representation of thinnings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Thinnings in TypOS  We first carefully worked out the trickier parts of the implementation in Agda  before porting the resulting code to Haskell.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This process highlighted a glaring  gap between on the one hand the experiments done using a strongly typed  inductive representation of thinnings and on the other hand their more efficient  but unsafe encoding in Haskell.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Agda  The Agda-based experiments use inductive families that make the key  invariants explicit which helps tracking complex constraints and catches design  flaws at typechecking time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The indices guarantee that we always transform the  12  thinnings appropriately when we add or remove bound variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Idris 2, the  inductive family representation of thinnings would be written:  data Thinning : (sx, sy : SnocList a) -> Type where  Done : Thinning [<] [<]  Keep : Thinning sx sy -> (0 x : a) -> Thinning (sx :< x) (sy :< x)  Drop : Thinning sx sy -> (0 x : a) -> Thinning sx (sy :< x)  The Thinning family is indexed by two scopes (represented as snoclists i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' lists  that are extended from the right, just like contexts in inference rules): sx the  tighter scope and sy the wider one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The Done constructor corresponds to a  thinning from the empty scope to itself ([<] is Idris 2 syntactic sugar for the  empty snoclist), and Keep and Drop respectively extend a given thinning by  keeping or dropping the most local variable (:< is the ‘snoc’ constructor, a sort  of flipped ‘cons’).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The ‘name’ (x of type a) is marked with the quantity 0 to  ensure it is erased at compile time (cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' section 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  During compilation, Idris 2 would erase the families’ indices as they are  forced (in the sense of Brady, McBride, and McKinna [BMM03]), and drop the  constructor arguments marked as runtime irrelevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The resulting inductive  type would be the following simple data type.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  data Thinning = Done | Keep Thinning | Drop Thinning  At runtime this representation is therefore essentially a linked list of booleans  (Done being Nil, and Keep and Drop respectively (True ::) and (False ::)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Haskell  The Haskell implementation uses this observation and picks a packed  encoding of this list of booleans as a pair of integers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' One integer represents the  length n of the list, and the other integer’s n least significant bits encode the  list as a bit pattern where 1 is Keep and 0 is Drop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Basic operations on thinnings are implemented by explicitly manipulating  individual bits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is not indexed and thus all the invariant tracking has to be  done by hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This has led to numerous and hard to diagnose bugs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Thinnings in Idris 2  Idris 2 is a self-hosting language whose core datatype is currently based on a  well-scoped de Bruijn representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This precise indexing of terms by their  scope helped entirely eliminate a whole class of bugs that plagued Idris 1’s  unification machinery.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  If we were to switch to a co-de Bruijn representation for our core language  we would want, and should be able, to have the best of both worlds: a safe and  efficient representation!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Thankfully Idris 2 implements Quantitative Type Theory (QTT) which gives  us a lot of control over what is to be runtime relevant and what is to be erased  during compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This should allow us to insist on having a high-level in-  terface that resembles an inductive family while ensuring that everything but  13  a pair of integers is erased at compile time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will exploit the key features of  QTT presented in section 3 to have our cake and eat it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5  An Efficient Invariant-Rich Representation  We can combine both approaches highlighted in section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2 by defining a record  parameterised by a source (sx) and target (sy) scopes corresponding to the two  ends of the thinnings, just like we would for the inductive family.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This record  packs two numbers and a runtime irrelevant proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Firstly, we have a natural number called bigEnd corresponding to the size of  the big end of the thinning (sy).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We are happy to use a (unary) natural number  here because we know that Idris 2 will compile it to an unbounded integer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Secondly, we have an integer called encoding corresponding to the thinning  represented as a bit vector stating, for each variable, whether it is kept or  dropped.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We only care about the integer’s bigEnd least significant bits and  assume the rest is set to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Thirdly, we have a runtime irrelevant proof invariant that encoding is in-  deed a valid encoding of size bigEnd of a thinning from sx to sy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will explore  the definition of the relation Invariant later on in section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  record Th {a : Type} (sx, sy : SnocList a) where  constructor MkTh  bigEnd : Nat  encoding : Integer  0 invariant : Invariant bigEnd encoding sx sy  The first sign that this definition is adequate is our ability to construct any  valid thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We demonstrate it is the case by introducing functions that act  as smart constructor analogues for the inductive family’s data constructors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Smart Constructors for Th  The first and simplest one is done, a function that packs a pair of 0 (the size of  the big end, and the empty encoding) together with a proof that it is an adequate  encoding of the thinning from the empty scope to itself.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In this instance, the  proof is simply the Done constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  done : Th [<] [<]  done = MkTh { bigEnd = 0, encoding = 0, invariant = Done }  To implement both keep and drop, we are going to need to perform bit-level  manipulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' These are made easy by Idris 2’s Bits interface which provides us  with functions to shift the bit patterns left or right (shiftl, shiftr), set or clear  bits at specified positions (setBit, clearBit), take bitwise logical operations like  disjunction (.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=') or conjunction (.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='&.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ), etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  14  In both keep and drop, we need to extend the encoding with an additional  bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' For this purpose we introduce the cons function which takes a bit b and an  existing encoding bs and returns the new encoding bs·b.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  cons : Bool -> Integer -> Integer  cons b bs = let bs0 = bs ‘shiftL‘ 1 in  if b then (bs0 ‘setBit‘ 0) else bs0  No matter what the value of the new bit is, we start by shifting the encoding  to the left to make space for it;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' this gives us bs0 which contains the bit pattern  bs·0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If the bit is True then we need to additionally set the bit at position 0  to obtain bs·1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Otherwise if the bit is False, we can readily return the bs·0  encoding obtained by left shifting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The correctness of this function is backed by  two lemma: testing the bit at index 0 after consing amounts to returning the  cons’d bit, and shifting the cons’d encoding to the right takes us back to the  unextended encoding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  testBit0Cons : (b : Bool) -> (bs : Integer) ->  testBit (cons b bs) 0 === b  consShiftR : (b : Bool) -> (bs : Integer) ->  (cons b bs) ‘shiftR‘ 1 === bs  The keep smart constructor demonstrates that from a thinning from sx to  sy and a runtime irrelevant variable x we can compute a thinning from the  extended source scope (sx :< x) to the target scope (sy :< x) where x was kept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  keep : Th sx sy -> (0 x : a) -> Th (sx :< x) (sy :< x)  keep th x = MkTh  { bigEnd = S (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='bigEnd)  , encoding = cons True (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding)  , invariant =  let 0 b = eqToSo $ testBit0Cons True (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding) in  Keep (rewrite consShiftR True (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding) in th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='invariant) x  }  The outer scope has grown by one variable and so we increment bigEnd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The  encoding is obtained by cons-ing the boolean True to record the fact that this  new variable is kept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Finally, we use the two lemmas shown above to convince  Idris 2 the invariant has been maintained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Similarly the drop function demonstrates that we can compute a thinning  getting rid of the variable x freshly added to the target scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  15  drop : Th sx sy -> (0 x : a) -> Th sx (sy :< x)  drop th x = MkTh  { bigEnd = S (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='bigEnd)  , encoding = cons False (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding)  , invariant =  let 0 prf = testBit0Cons False (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding)  0 nb = eqToSo $ cong not prf in  Drop (rewrite consShiftR False (th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding) in th .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='invariant) x  }  We once again increment the bigEnd, use cons to record that the variable is  being discarded and use the lemmas ensuring its correctness to convince Idris 2  the invariant is maintained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We can already deploy these smart constructors to implement functions pro-  ducing thinnings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We use which as our example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is a filter-like function that  returns a dependent pair containing the elements that satisfy a boolean predi-  cate together with a proof that there is a thinning embedding them back into  the input snoclist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  which : (a -> Bool) -> (sy : SnocList a) ->  (sx : SnocList a ** Th sx sy)  which p [<] = ([<] ** done)  which p (sy :< y) =  let (sx ** th) = which p sy in  if p y then (sx :< y ** keep th y)  else (sx ** drop th y)  If the input snoclist is empty then the output shall also be, and done builds  a thinning from [<] to itself.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it is not empty we can perform a recursive call  on the tail of the snoclist and then depending on whether the predicates holds  true of the head we can either keep or drop it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We are now equipped with these smart constructors that allow us to seam-  lessly build thinnings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  To recover the full expressive power of the inductive  family, we also need to be able to take these thinnings apart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We are now going  to tackle this issue.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Pattern Matching on Th  The View family is a sum type indexed by a thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It has one data constructor  associated to each smart constructor and storing its arguments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  data View : Th sx sy -> Type where  Done : View done  Keep : (th : Th sx sy) -> (0 x : a) -> View (keep th x)  Drop : (th : Th sx sy) -> (0 x : a) -> View (drop th x)  The accompanying view function witnesses the fact that any thinning arises  as one of these three cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  16  view : (th : Th sx sy) -> View th  We show the implementation of view in its entirety but leave out the tech-  nical auxiliary lemma it invokes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The interested reader can find them in the  accompanying material.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will however inspect the code view compiles to af-  ter erasure in section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='5 to confirm that these auxiliary definitions do not incur  any additional runtime cost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We first start by pattern matching on the bigEnd of the thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it is 0  then we know the thinning has to be the empty thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Thanks to an inversion  lemma called isDone, we can collect a lot of equality proofs: the encoding bs has  to be 0, the source and target scopes sx and sy have to be the empty snoclists,  and the proof prf of the invariant has to be of a specific shape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Rewriting by  these equalities changes the goal type enough for the typechecker to ultimately  see that the thinning was constructed using the done smart constructor and so  we can use the view’s Done constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  view (MkTh 0 bs prf) =  let 0 eqs = isDone prf in  rewrite bsIsZero eqs in  rewrite fstIndexIsLin eqs in  rewrite sndIndexIsLin eqs in  rewrite invariantIsDone eqs in  Done  In case the thinning is non-empty, we need to inspect the 0-th bit of the  encoding to know whether it keeps or discards its most local variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is  done by calling the choose function which takes a boolean b and returns a value  of type (Either (So b) (So (not b)) i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' we not only inspect the boolean but also  record which value we got in a proof using the So family introduced in section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  view (MkTh (S i) bs prf) = case choose (testBit bs Z) of  If the bit is set then we know the variable is kept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' And so we can invoke an  inversion lemma that will once again provide us with a lot of equalities that we  immediately deploy to reshape the goal’s type.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This ultimately lets us assemble  a sub-thinning and use the view’s Keep constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Left so =>  let 0 eqs = isKeep prf so in  rewrite fstIndexIsSnoc eqs in  rewrite sndIndexIsSnoc eqs in  rewrite invariantIsKeep eqs in  rewrite isKeepInteger bs so in  let th : Th eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='fstIndexTail eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='sndIndexTail  th = MkTh i (bs ‘shiftR‘ 1) eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='subInvariant in  cast $ Keep th eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='keptHead  If the bit is not set then we learn that the thinning was constructed using  17  drop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We can once again use an inversion lemma to rearrange the goal and  finally invoke the view’s Drop constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Right soNot =>  let 0 eqs = isDrop prf soNot in  rewrite sndIndexIsSnoc eqs in  rewrite invariantIsDrop eqs in  rewrite isDropInteger bs soNot in  let th : Th sx eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='sndIndexTail  th = MkTh i (bs ‘shiftR‘ 1) eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='subInvariant in  cast $ Drop th eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='keptHead  We can readily use this function to implement pattern matching functions  taking a thinning apart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We can for instance define kept, the function that  counts the number of keep smart constructors used when manufacturing the  input thinning and returns a proof that this is exactly the length of the source  scope sx.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  kept : Th sx sy -> (n : Nat ** length sx === n)  kept th = case view th of  Done  => (0 ** Refl)  Keep th x => let (n ** eq) = kept th in  (S n ** cong S eq)  Drop th x => kept th  We proceed by calling the view function on the input thinning which im-  mediately tells us that we only have three cases to consider.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The Done case is  easily handled because the branch’s refined types inform us that both sx and  sy are the empty snoclist [<] whose length is evidently 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In the Keep branch  we learn that sx has the shape (_ :< x) and so we must return the successor of  whatever the result of the recursive call gives us.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Finally in the Drop case, sx  is untouched and so a simple recursive call suffices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Note that the function is  correctly detected as total because the target scope sy is indeed getting struc-  turally smaller at every single recursive call.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It is runtime irrelevant but it can  still be successfully used as a termination measure by the compiler.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3  The Invariant Relation  We have shown the user-facing Th and have claimed that it is possible to define  smart constructors done, keep, and drop, as well as a view function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This should  become apparent once we show the actual definition of Invariant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Definition of Invariant  The relation maintains the invariant between the record’s fields bigEnd (a Nat)  and encoding (an Integer) and the index scopes sx and sy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Its definition can  favour ease-of-use of runtime efficiency because we statically know that all of  18  the Invariant proofs will be erased during compilation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  data Invariant : (i : Nat) -> (bs : Integer) ->  (sx, sy : SnocList a) -> Type where  Done : Invariant Z 0 [<] [<]  Keep : Invariant i (bs ‘shiftR‘ 1) sx sy -> (0 x : a) ->  {auto 0 b  : So (testBit bs Z)} ->  Invariant (S i) bs (sx :< x) (sy :< x)  Drop : Invariant i (bs ‘shiftR‘ 1) sx sy -> (0 x : a) ->  {auto 0 nb : So (not (testBit bs Z))} ->  Invariant (S i) bs sx (sy :< x)  As always, the Done constructor is the simplest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It states that the thinning  of size Z and encoded as the bit pattern 0 is the empty thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The Keep constructor guarantees that the thinning of size (S i) and encoding  bs represents an injection from (sx :< x) to (sy :< x) provided that the bit at  position Z of bs is set, and that the rest of the bit pattern (obtained by a right  shift on bs) is a valid thinning of size i from sx to sy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The Drop constructor is structured the same way, except that it insists the  bit at position Z should not be set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We can readily use this relation to prove that some basic encoding are valid  representations of useful thinnings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Examples of Invariant proofs  For instance, we can always define a thinning from the empty scope to an  arbitrary scope sy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  none : (sy : SnocList a) -> Th [<] sy  none sy = MkTh (length sy) 0 (none sy)  The encoding of this thinning is 0 because every variable is being discarded  and its bigEnd is the length of the outer scope sy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The proof that this encoding  is valid is provided by the none lemma proven below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We once again use Idris 2’s  overloading to give the same to functions that play similar roles but at different  types.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  none : (sy : SnocList a) -> Invariant (length sy) 0 [<] sy  none [<] = Done  none (sy :< y) = Drop (none sy) y  The proof proceeds by induction over the outer scope sy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it is empty,  we can simply use the constructor for the empty thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Otherwise we can  invoke Drop on the induction hypothesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This all typechecks because (testBit  0 Z) computes to False and so the nb proof can be constructed automatically  by Idris 2’s proof search (cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2), and (0 ‘shiftR‘ 1) evaluates to 0  which means the induction hypothesis has exactly the right type.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  19  The definition of the identity thinning is a bit more involved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' For a scope of  size n, we are going to need to generate a bit pattern consisting of n ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We  define it in two steps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' First, cofull defines a bit pattern of k zeros followed by  infinitely many ones by shifting k places to the left a bit pattern of ones only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Then, we obtain full by taking the complement of cofull.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  cofull : Nat -> Integer  cofull n = oneBits ‘shiftL‘ n  full : Nat -> Integer  full n = complement (cofull n)  We can then define the identity thinning for a scope of size n by pairing  (full n) as the encoding and n as the bigEnd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  ones : (sx : SnocList a) -> Th sx sx  ones sx = let n : Nat;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' n = length sx in MkTh n (full n) (ones sx)  The bulk of the work is once again in the eponymous lemma proving that  this encoding is valid.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  ones : (sx : SnocList a) ->  let n = length sx in Invariant n (full n) sx sx  ones [<] = Done  ones (sx :< x) =  let 0 nb = eqToSo (testBitFull (S (length sx)) Z) in  Keep (rewrite shiftRFull (length sx) in ones sx) x  This proof proceeds once more by induction on the scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If the scope is  empty then once again the constructor for the empty thinning will do.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In the  non-empty case, we first appeal to an auxiliary lemma (not shown here) to con-  struct a proof nb that the bit at position Z for a non-zero full integer is known  to be True.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We then need to use another lemma to cast the induction hypothesis  which mentions (full (length sx)) so that it may be used in a position where  we expect a proof talking about (full (length (sx :< x)) ‘shiftR‘ 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3  Properties of the Invariant relation  This relation has a lot of convenient properties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  First, it is proof irrelevant: any two proofs that the same i, bs, sx, and sy  are related are provably equal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Consequently, equality on Th values amounts to  equality of the bigEnd and encoding values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In particular it is cheap to test  whether a given thinning is the empty or the identity thinning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Second, it can be inverted [CT95] knowing only two bits: whether the natural  number is empty and what the value of the bit at position Z of the encoding  is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is what allowed us to efficiently implement the view function by using  these two checks and then inverting the Invariant proof to gain access to the  proof that the remainder of the thinning’s encoding is valid.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We will see in  section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='5 that this leads to efficient runtime code for the view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  20  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='4  Choose Your Own Abstraction Level  Access to both the high-level View and the internal Invariant relation means  that programmers can pick the level of abstraction at which they want to work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  They may need to explicitly manipulate bits to implement key operators that  are used in performance-critical paths but can also stay at the highest level for  more negligible operations, or when proving runtime irrelevant properties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In the previous section we saw simple examples of these bit manipulations  when defining none (using the constant 0 bit pattern) and ones using bit shifting  and complement to form an initial segment of 1s followed by 0s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Other natural examples include the meet and join of two thinnings sharing  the same wider scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The join can for instance be thought of either as a  function defined by induction on the first thinning and case analysis on the  second, emitting a Keep constructor whenever either of the inputs does.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Or we  can observe that the bit pattern in the join is exactly the disjunction of the  inputs’ respective bit patterns and prove a lemma about the Invariant relation  instead.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This can be visualised as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In each column, the meet is a •  whenever either of the inputs is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  ◦◦••◦  ∨ •◦◦••  •◦•••  The join is of particular importance because it appears when we convert  an ‘opened’ view of a term into its co-de Bruijn counterpart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' As we mentioned  earlier, co-de Bruijn terms in an arbitrary scope are represented by the pairing of  a term indexed by its precise support with a thinning embedding this support  back into the wider scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  When working with such a representation, it is  convenient to have access to an ‘opened’ view where the outer thinning has  been pushed inside therefore exposing the term’s top-level constructor, ready  for case-analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The following diagram shows the correspondence between an ‘opened’ ap-  plication node using the view (the diamond ‘$’ node) with two subterms both  living in the outer scope and its co-de Bruijn form (the circular ‘$’ node) with  an outer thinning selecting the term support.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  $  t1  t2  ◦◦••◦  •◦◦••  $  t1  t2  •◦•••  ◦••◦  •◦••  The outer thinning of the co-de Bruijn term is obtained precisely by com-  puting the join of the respective outer thinnings of the ‘opened’ application’s  function and argument.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  These explicit bit manipulations will be preserved during compilation and  thus deliver more efficient code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  21  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='5  Compiled Code  The following code block shows the JavaScript code that is produced when  compiling the view function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We chose to use the JavaScript backend rather  than e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' the ChezScheme one because it produces fairly readable code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We  have modified the backend to also write comments reminding the reader of the  type of the function being defined and the data constructors the natural number  tags correspond to.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' These changes are now available to all in Idris 2’s current  development version.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The only manual modifications we have performed are the inlining of a func-  tion corresponding to a case block, renaming variables and property names to  make them human-readable, introducing the $tail definitions to make lines  shorter, and slightly changing the layout.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  /* Thin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='Smart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='view : (th : Th sx sy) -> View th */  function Thin_Smart_view($th) {  switch($th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='bigEnd) {  case 0n: return {h: 0 /* Done */};' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  default: {  const $predBE = ($th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='bigEnd-1n);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  const $test = choose(notEq(($th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding&1n), 0n)));' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  switch($test.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='tag) {  case 0: /* Left */ {  const $tail = $th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding>>1n;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  return { tag: 1 /* Keep */  , val: {bigEnd: $predBE, encoding: $tail}};' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' }  case 1: /* Right */ {  const $tail = $th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='encoding>>1n;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  return { tag: 2 /* Drop */  , val: {bigEnd: $predBE, encoding: $tail}};' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' }  }}}}  Readers can see that the compilation process has erased all of the indices  and the proofs showing that the invariant tying the efficient runtime represen-  tation to the high-level specification is maintained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A thinning is represented  at runtime by a JavaScript object with two properties corresponding to Th’s  runtime relevant fields: bigEnd and encoding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Both are storing a JavaScript  bigInt (one corresponding to the Nat, the other to the Integer).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' For instance  the thinning [01101] would be at runtime { bigEnd: 5n, encoding: 13n }.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The view proceeds in two steps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' First if the bigEnd is 0n then we know the  thinning is empty and can immediately return the Done constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Otherwise  we know the thinning to be non-empty and so we can compute the big end of its  tail ($predBE) by subtracting one to the non-zero bigEnd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We can then inspect  the bit at position 0 to decide whether to return a Keep or a Drop constructor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  This is performed by using a bit mask to 0-out all the other bits ($th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='bigEnd&1n)  and checking whether the result is zero.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it is not equal to 0 then we emit  22  Keep and compute the $tail of the thinning by shifting the original encoding  to drop the 0th bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Otherwise we emit Drop and compute the same tail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  By running view on this [01101] thinning, we would get back (Keep [0110]),  that is to say { tag: 1, val: { bigEnd: 4n, encoding: 6n } }.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Thanks to Idris 2’s implementation of Quantitative Type Theory we have  managed to manufacture a high level representation that can be manipulated  like a classic inductive family using smart constructors and views without giving  up an inch of control on its runtime representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The remaining issues such as the fact that we form the view’s constructors  only to immediately take them apart thus creating needless allocations can be  tackled by reusing Wadler’s analysis (section 12 of [Wad87]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  6  Conclusion  We have seen that inductive families provide programmers with ways to root out  bugs by enforcing strong invariants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Unfortunately these families can get in the  way of producing performant code despite existing optimisation passes erasing  redundant or runtime irrelevant data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This tension has led us to take advantage  of Quantitative Type Theory in order to design a library combining the best of  both worlds: the strong invariants and ease of use of inductive families together  with the runtime performance of explicit bit manipulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Related Work  For historical and ergonomic reasons, idiomatic code in Coq tends to center  programs written in a subset of the language quite close to OCaml and then  prove properties about these programs in the runtime irrelevant Prop fragment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  This can lead to awkward encodings when the unrefined inputs force the user  to consider cases which ought to be impossible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Common coping strategies in-  volve relaxing the types to insert a modicum of partiality e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' returning an  option type or taking an additional input to be used as the default return value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  This approach completely misses the point of type-driven development.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We  benefit a lot from having as much information as possible available during in-  teractive editing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  This information not only helps tremendously getting the  definitions right by ensuring we always maintain vital invariants thus making  invalid states unrepresentable, it also gives programmers access to type-driven  tools and automation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Thankfully libraries such as Equations [Soz10, SM19]  can help users write more dependently typed programs, by taking care of the  complex encoding required in Coq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A view-based approach similar to ours but  using Prop instead of the zero quantity ought to be possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We expect that  the views encoded this way in Coq will have an even worse computational be-  haviour given that Equations uses a sophisticated elaboration process to encode  dependent pattern-matching into Gallina.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' However Coq does benefit from good  automation support for unfolding lemmas, inversion principles, and rewriting  23  by equalities which may compensate for the awkwardness introduced by the  encoding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Prior work on erasure [Tej20] has the advantage of offering a fully automated  analysis of the code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The main inconvenience is that users cannot state explic-  itly that a piece of data ought to be runtime irrelevant and so they may end  up inadvertently using it which would prevent its erasure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Quantitative Type  Theory allows us users to explicitly choose what is and is not runtime relevant,  with the quantity checker keeping us true to our word.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This should ensure that  the resulting program has a much more predictable complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A somewhat related idea was explored by Brady, McKinna, and Hammond  in the context of circuit design [BMH07].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In their verification work they index  an efficient representation (natural numbers as a list of bits) by its meaning  as a unary natural number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' All the operations are correct by construction as  witnessed by the use of their unary counterparts acting as type-level specifica-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In the end their algorithms still process the inductive family instead of  working directly with binary numbers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This makes sense in their setting where  they construct circuits and so are explicitly manipulating wires carrying bits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  By contrast, in our motivating example we really want to get down to actual  (unbounded) integers rather than linked lists of bits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Limitations and Future Work  Overall we found this case study using Idris 2, a state of the art language based  on Quantitative Type Theory, very encouraging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The language implementation  is still experimental (see for instance appendix B for some of the bugs we found)  but none of the issues are intrinsic limitations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We hope to be able to push  this line of work further, tackling the following limitations and exploring more  advanced use cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Limitations  Unfortunately it is only propositionally true that (view (keep th x)) computes  to (Keep th x) (and similarly for done/Done and drop/Drop).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This means that  users may need to manually deploy these lemmas when proving the properties  of functions defined by pattern matching on the result of calling the view func-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This annoyance would disappear if we had the ability to extend Idris 2’s  reduction rules with user-proven equations as implemented in Agda and formally  studied by Cockx, Tabareau, and Winterhalter [CTW21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In this paper’s case study, we were able to design the core Invariant relation  making the invariants explicit in such a way that it would be provably proof  irrelevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This may not always be possible given the type theory currently im-  plemented by Idris 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Adding support for a proof-irrelevant sort of propositions  (see e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Altenkirch, McBride, and Swierstra’s work [AMS07]) could solve this  issue once and for all.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  The Idris 2 standard library thankfully gave us access to a polished pure  interface to explicitly manipulate an integer’s bits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' However these built-in oper-  24  ations came with no built-in properties whatsoever.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' And so we had to postulate  a (minimal) set of axioms (see appendix A) and prove a lot of useful corollar-  ies ourselves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' There is even less support for other low-level operations such as  reading from a read-only array, or manipulating pointers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We also found the use of runtime irrelevance (the 0 quantity) sometimes  somewhat frustrating.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Pattern-matching on a runtime irrelevant value in a  runtime relevant context is currently only possible if it is manifest for the  compiler that the value could only arise using one of the family’s construc-  tors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In non-trivial cases this is unfortunately only merely provable rather  than self-evident.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Consequently we are forced to jump through hoops to ap-  pease the quantity checker, and end up defining complex inversion lemmas to  bypass these limitations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This could be solved by a mix of improvements to  the typechecker and meta-programming using prior ideas on automating inver-  sion [CT95, McB96, Mon10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Future work  We are planning to explore more memory-mapped representations equipped  with a high level interface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We already have experimental results demonstrating that we can use a read-  only array as a runtime representation of a binary search tree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Search can be  implemented as a proven-correct high level decision procedure that is seem-  ingly recursively exploring the ”tree”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' At runtime however, this will effectively  execute like a classic search by dichotomy over the array.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  More generally, we expect that a lot of the work on programming on serialised  data done in LoCal [VKR+19] thanks to specific support from the compiler can  be done as-is in a QTT-based programming language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Indeed, QTT’s type  system is powerful enough that tracking these invariants can be done purely in  library code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In the short term, we would like to design a small embedded domain specific  language giving users the ability to more easily build and take apart products  and sums efficiently represented in the style we presented here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Staging would  help here to ensure that the use of the eDSL comes at no runtime cost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' There  are plans to add type-enforced staging to Idris 2, thus really making it the ideal  host language for our project.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Our long term plan is to go beyond read-only data and look at imperative  programs proven correct using separation logic and see how much of this after-  the-facts reasoning can be brought back into the types to enable a high-level  correct-by-construction programming style that behaves the same at runtime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Acknowledgements  We are grateful to Conor McBride for discussions per-  taining to the fine details of the unsafe encoding used in TypOS, as well as James  McKinna, Fredrik Nordvall Forsberg, Ohad Kammar, and Jacques Carette for  providing helpful comments and suggestions on early versions of this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  25  References  [AAM+22] Guillaume Allais, Malin Altenm¨uller,  Conor McBride, Georgi  Nakov, Fredrik Nordvall Forsberg, and Craig Roy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' TypOS: An oper-  ating system for typechecking actors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In 28th International Confer-  ence on Types for Proofs and Programs, TYPES 2022, June 20-25,  2022, Nantes, France, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [AMS07]  Thorsten Altenkirch, Conor McBride, and Wouter Swierstra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Ob-  servational equality, now!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Aaron Stump and Hongwei Xi, editors,  Proceedings of the ACM Workshop Programming Languages meets  Program Verification, PLPV 2007, Freiburg, Germany, October 5,  2007, pages 57–68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content=' Syntax and semantics of quantitative type theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content=' 2007, volume 8 of Trends in Functional Programming, pages  159–176.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content=' In  Anders Møller and Manu Sridharan, editors, 35th European Confer-  ence on Object-Oriented Programming, ECOOP 2021, July 11-17,  2021, Aarhus, Denmark (Virtual Conference), volume 194 of LIPIcs,  pages 9:1–9:26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Schloss Dagstuhl - Leibniz-Zentrum f¨ur Informatik,  2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [CA20]  Jesper Cockx and Andreas Abel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Elaborating dependent (co)pattern  matching: No pattern left behind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content=' Automating inversion of in-  ductive predicates in coq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Stefano Berardi and Mario Coppo,  editors, Types for Proofs and Programs, International Workshop  TYPES’95, Torino, Italy, June 5-8, 1995, Selected Papers, volume  1158 of Lecture Notes in Computer Science, pages 85–104.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content='  [CTW21]  Jesper Cockx, Nicolas Tabareau, and Th´eo Winterhalter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The tam-  ing of the rew: a type theory with computational assumptions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  ACM Program.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Lang.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content='  [dB72]  Nicolaas Govert de Bruijn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Lambda calculus notation with nameless  dummies, a tool for automatic formula manipulation, with appli-  cation to the Church-Rosser theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content='  Inductive families.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Formal Aspects Comput.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content=' Inverting inductively defined relations in LEGO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+page_content=' Springer, 1996.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [McB16]  Conor McBride.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  I got plenty o’ nuttin’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In Sam Lindley, Conor  McBride, Philip W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Trinder, and Donald Sannella, editors, A List of  Successes That Can Change the World - Essays Dedicated to Philip  Wadler on the Occasion of His 60th Birthday, volume 9600 of Lec-  ture Notes in Computer Science, pages 207–233.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Springer, 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [McB18]  Conor McBride.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Everybody’s got to be somewhere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In Robert  Atkey and Sam Lindley, editors, Proceedings of the 7th Workshop on  Mathematically Structured Functional Programming, MSFP@FSCD  2018, Oxford, UK, 8th July 2018, volume 275 of EPTCS, pages 53–  69, 2018.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [MEL+21] Krzysztof Maziarz, Tom Ellis, Alan Lawrence, Andrew W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Fitzgib-  bon, and Simon Peyton Jones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Hashing modulo alpha-equivalence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In Stephen N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Freund and Eran Yahav, editors, PLDI ’21: 42nd  ACM SIGPLAN International Conference on Programming Lan-  guage Design and Implementation, Virtual Event, Canada, June  20-25, 2021, pages 960–973.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ACM, 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [MM04]  Conor McBride and James McKinna.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' The view from the left.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Funct.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Program.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=', 14(1):69–111, 2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [Mon10]  Jean-Fran¸cois Monin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Proof Trick: Small Inversions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Yves Bertot,  editor, Second Coq Workshop, Edinburgh, United Kingdom, July  2010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Yves Bertot.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  27  [SM19]  Matthieu Sozeau and Cyprien Mangin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Equations reloaded: high-  level dependently-typed functional programming and proving in coq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ACM Program.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Lang.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=', 3(ICFP):86:1–86:29, 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [Soz10]  Matthieu Sozeau.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Equations: A dependent pattern-matching com-  piler.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Matt Kaufmann and Lawrence C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Paulson, editors, Inter-  active Theorem Proving, First International Conference, ITP 2010,  Edinburgh, UK, July 11-14, 2010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Proceedings, volume 6172 of Lec-  ture Notes in Computer Science, pages 419–434.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Springer, 2010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [Tej20]  Mat´uˇs Tejiˇsˇc´ak.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A dependently typed calculus with pattern  matching and erasure inference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ACM Program.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Lang.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=',  4(ICFP):91:1–91:29, 2020.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [VKR+19] Michael Vollmer, Chaitanya Koparkar, Mike Rainey, Laith Sakka,  Milind Kulkarni, and Ryan R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Newton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Local: a language for pro-  grams operating on serialized data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Kathryn S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' McKinley and  Kathleen Fisher, editors, Proceedings of the 40th ACM SIGPLAN  Conference on Programming Language Design and Implementation,  PLDI 2019, Phoenix, AZ, USA, June 22-26, 2019, pages 48–62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  ACM, 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [Wad87]  Philip Wadler.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Views: A way for pattern matching to cohabit with  data abstraction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Conference Record of the Fourteenth Annual  ACM Symposium on Principles of Programming Languages, Mu-  nich, Germany, January 21-23, 1987, pages 307–313.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ACM Press,  1987.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  [WB89]  Philip Wadler and Stephen Blott.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' How to make ad-hoc polymor-  phism less ad-hoc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' In Conference Record of the Sixteenth Annual  ACM Symposium on Principles of Programming Languages, Austin,  Texas, USA, January 11-13, 1989, pages 60–76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' ACM Press, 1989.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A  Postulated lemmas for the Bits interface  It is often more convenient to reason about integers in terms of their bits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' We  define the notion of bitwise equality as the pointwise equality according to the  testBit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  (˜˜˜) : Integer -> Integer -> Type  bs ˜˜˜ cs = (i : Nat) -> testBit bs i === testBit cs i  Our first postulate is a sort of extensionality principle stating that bitwise  equality implies propositional equality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  extensionally : {bs, cs : Integer} -> bs ˜˜˜ cs -> bs === cs  28  This gives us a powerful reasoning principle once combined with axioms  explaining the behaviour of various primitives at the bit level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  This is why  almost all of the remaining axioms are expressed in terms of testBit calls.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Logical operations  Our first batch of axioms relates logical operations on integers to their boolean  counterparts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is essentially stating that these operations are bitwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  testBitAnd : (bs, cs : Integer) -> (i : Nat) ->  testBit (bs .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='&.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' cs) i === (testBit bs i && testBit cs i)  testBitOr : (bs, cs : Integer) -> (i : Nat) ->  testBit (bs .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' cs) i === (testBit bs i || testBit cs i)  testBitComplement : (bs : Integer) -> (i : Nat) ->  testBit (complement bs) i === not (testBit bs i)  Together with the extensionality principle mentioned above this already al-  lows us to prove for instance that the binary operators are commutative and  associative, that the de Morgan laws hold, or that conjunction distributes over  disjunction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Bit Shifting  The second set of axiom describes the action of left and right shifting on bit  patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  A right shift of size k will drop the k least significant bits;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' consequently  testing the bit i on the right-shifted integer amounts to testing the bit (k + i)  on the original integer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  testBitShiftR : (bs : Integer) -> (k : Nat) ->  (i : Nat) -> testBit (bs ‘shiftR‘ k) i === testBit bs (k + i)  A left shift will add k new least significant bits initialised at 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' consequently  testing a bit i on the left-shifted integer will either return False if i is strictly  less than k, or the bit at position (i - k) in the original integer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  For simplicity we state these results without mentioning the ‘strictly less  than’ relation, by considering on the one hand the effect of a non-zero left shift,  and on the other the fact that a left-shift by 0 bits is the identity function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  testBit0ShiftL : (bs : Integer) -> (k : Nat) ->  testBit (bs ‘shiftL‘ S k) Z === False  testBitSShiftL : (bs : Integer) -> (k : Nat) -> (i : Nat) ->  testBit (bs ‘shiftL‘ S k) (S i) === testBit (bs ‘shiftL‘ k) i  29  shiftL0 : (bs : Integer) -> (bs ‘shiftL‘ 0) === bs  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3  Bit testing  The last set of axioms specifies what happens when a bit is set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Testing a bit other than the one that was set amounts to testing it on the  original integer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  testSetBitOther : (bs : Integer) -> (i, j : Nat) -> Not (i === j) ->  testBit (setBit bs i) j === testBit bs j  Finally, we have an axiom stating that the integer (bit i) (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' 2i) is non-  zero.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  bitNonZero : (i : Nat) -> (bit i == 0) === False  B  Current Limitations of Idris 2  This challenge, suggested by Jacques Carette, highlights some of the current  limitations of Idris 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='1  Problem statement  The goal is to use the Vect type defined in section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3 and define a view that  un-does vector-append.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is a classic exercise in dependently-typed program-  ming, the interesting question being whether we can implement the function just  as seamlessly with our encoding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Vector append can easily be defined by induction over the first vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  (++) : Vect m a -> Vect n a -> Vect (m + n) a  xs@_ ++ ys with (view xs)  _ | [] = ys  _ | hd :: tl = hd :: (tl ++ ys)  If the first vector is empty we can readily return the second vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' If it  is cons-headed, we can return the head and compute the tail by performing a  recursive call.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Equipped with this definition, we can declare the view type which we call  SplitAt by analogy with its weakly typed equivalent processing lists.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' It states  that a vector xs of length p can be split at m if p happens to be (m + n) and xs  happens to be (pref ++ suff) where pref and suff’s respective lengths are m  and n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  30  data SplitAt : (m : Nat) -> (xs : Vect p a) -> Type where  MkSplitAt : (pref : Vect m a) -> (suff : Vect n a) ->  SplitAt m (pref ++ suff)  The challenge is to define the function proving that a vector of size (m + n)  can be split at m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='2  Failing attempts  The proof will necessarily go by induction on m, followed by a case analysis on  the input vector and a recursive call in the non-zero case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  Our first failing attempt successfully splits the natural number, calls the view  on the vector xs to take it apart but then fails when performing the recursive  call to splitAt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  failing "tl is not accessible in this context"  splitAt : (m : Nat) -> (xs : Vect (m + n) a) -> SplitAt m xs  splitAt 0 xs = MkSplitAt [] xs  splitAt (S m) xs@_ with (view xs)  _ | hd :: tl@_ with (splitAt m tl)  _ | res = ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='a  This reveals an issue in Idris 2’s handling of the interplay between @-patterns  and quantities: the compiler arbitrarily decided to make the alias tl runtime  irrelevant only to then complain that tl is not accessible when we want to  perform the recursive call (splitAt m tl)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  In order to work around this limitation, we decided to let go of @-patterns  and write the fully explicit clause ourselves, using dotted patterns to mark the  forced expressions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  failing "Can’t match on ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='postpone [no locals in scope] (User dotted)"  splitAt : (m : Nat) -> (xs : Vect (m + n) a) -> SplitAt m xs  splitAt 0 xs = MkSplitAt [] xs  splitAt (S m) xs@_ with (view xs)  _ | hd :: tl with (splitAt m tl)  splitAt (S m) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (hd :: (pref ++ suff))  | hd :: .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' (pref ++ suff)  | MkSplitAt pref suff = ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='a  The left-hand side now typechecks but the case tree builder fails with a  perplexing error.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This reveals a bug in Idris 2’s implementation of elaboration of  pattern-matching functions to case trees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Instead of ignoring dotted expressions  when building the case tree (these expressions are forced and so the variables  they mention will have necessarily been bound in another pattern), it attempts  to use them to drive the case-splitting strategy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' This is a well-studied problem  and should be fixable by referring to Cockx and Abel’s work [CA20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  31  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='3  Working Around Idris 2’s Limitations  This leads us to our working solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' Somewhat paradoxically, working around  these Idris 2 bugs led us to a more principled solution whereby the pattern-  matching step needed to adjust the result returned by the recursive call is ab-  stracted away in an auxiliary function whose type clarifies what is happening.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  From an m split on xs, we can easily compute an (S m) split on (x :: xs) by  cons-ing x on the prefix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  (::) : (x : a) -> SplitAt m xs -> SplitAt (S m) (x :: xs)  x :: MkSplitAt pref@(MkVect _ Refl) suff  = MkSplitAt (x :: pref) suff  In this auxiliary function, xs is clearly runtime irrelevant and so the case-  splitter will not attempt to inspect it, thus generating the correct case tree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We are forced to match further on pref (in particular by making the equality  proof Refl) so that just enough computation happens at the type level for the  typechecker to see that things do line up.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content=' A proof irrelevant type of propositional  equality would have helped us here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  We can put all of these pieces together and finally get our splitAt view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  splitAt : (m : Nat) -> (xs : Vect (m + n) a) -> SplitAt m xs  splitAt 0 xs = MkSplitAt [] xs  splitAt (S m) xs@_ with (view xs)  _ | hd :: tl = hd :: splitAt m tl  We do want to reiterate that these limitations are not intrinsic limitations of  the approach, there are just flaws in the current experimental implementation  of the Idris 2 language and can and should be remedied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
+page_content='  32' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/D9E0T4oBgHgl3EQfQgCE/content/2301.02194v1.pdf'}
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+arXiv:2301.04227v1  [hep-th]  10 Jan 2023
+Induced energy-momentum tensor in de Sitter scalar QED and its implication for
+induced current
+Omid Gholizadeh Meimanat and Ehsan Bavarsad∗
+Department of Physics, University of Kashan, 8731753153 Kashan, Iran
+The aim of this research is to investigate the vacuum energy-momentum tensor of a quantized,
+massive, nonminimally coupled scalar field induced by a uniform electric field background in a four-
+dimensional de Sitter spacetime (dS4). We compute the expectation value of the energy-momentum
+tensor in the in-vacuum state and then regularize it using the adiabatic subtraction procedure.
+The correct trace anomaly of the induced energy-momentum tensor that confirmed our results is
+significant. The nonconservation equation for the induced energy-momentum tensor imposes the
+renormalization condition for the induced electric current of the scalar field. The findings of this
+research indicate that there are significant differences between the two induced currents which are
+regularized by this renormalization condition and the minimal subtraction condition.
+I.
+INTRODUCTION
+In the past several decades quantum field theory in curved spacetime has played a major role in the study of
+the effects of gravity on quantum fields; for an pedagogical introduction see [1–3]. A precise understanding of the
+quantum effects in curved spacetime was acquired by the late 1960s by Parker [4–6] and followed by investigations of
+others. Indeed, these early investigations focused primarily on the physical consequences of particle creation in the
+cosmological spacetimes. It has been illustrated that a time-varying gravitational field creates elementary particles
+from the vacuum. Parker discovered that this particle creation process can be analyzed by using the Bogoliubov
+transformations method [5]. Formulating a general framework of quantum field theory in curved spacetime involves
+nontrivial questions.
+The problem of particle concept is a deep one, and it is associated with one of the most
+fundamental difficulties of quantum field theory in curved spacetime, that there is no an unambiguous or unique
+vacuum state; a detailed discussion can be found in [1, 2]. This ambiguity is reflected in the theory by the absence of
+an unambiguous or unique preferred mode solutions of the field equation, which is in turn a consequence of symmetry
+group of the spacetime. Since in a general nonstatic curved spacetime there is generically no any timelike Killing
+vector field, it is not possible to classify modes as positive-frequency or negative-frequency. Indeed, it is possible to
+construct a compleat set of modes, however the problem is that there are many of such sets and we will not have
+any criterion available to select a unique privileged choice of the modes. One of the key lessens learned from the
+development of this subject is that the notion of particle number does not generally have universal significant. Hence,
+the expectation value of the energy-momentum tensor in a suitable vacuum state is perhaps more physically relevant
+object to probe the structure of quantum fields in curved spacetime rather than particle number quantity [1]. Part of
+reason is that the expectation value of the energy-momentum tensor in a fixed vacuum state transforms according to
+the usual tensor transformation law. In particular, if the vacuum expectation value of the energy-momentum tensor
+vanishes for an observer, it will vanish for all observers. On the contrary, the expectation of particle number is an
+essential observer-dependent quantity. The energy-momentum tensor is also important, because it is directly relevant
+to explore the consequences of the quantum field dynamics for the geometry of the spacetime through the Einstein
+equation. Hence, it is interesting to investigate the expectation value of the energy-momentum tensor in a suitable
+vacuum state.
+Since the mid-seventies, significant advances have been made in the computation of the energy-momentum tensor of
+the quantum fields as well as its applications in the cosmological context. An essential feature of these computations
+is that they all involve the ultraviolet divergencies.
+In fact, such divergencies occur naturally in quantum field
+theory calculations. Various prescriptions have been developed for rendering the energy-momentum tensor finite.
+Among these prescriptions, Pauli-Villars regularization [7, 8], dimensional regularization [9–11], and zeta-function
+regularization [11–14] were originally developed for use in Minkowski spacetime. Several sets of fictitious fields may
+be necessary to remove all of the divergences, making Pauli-Villars regularization rather complicated. In [13], it was
+pointed out that dimensional regularization procedure is ambiguous in curved spacetime due to the fact that in some
+classes of spacetimes, there is no natural way to generalize the dimensionality of the spacetime and the answer would
+be different in different extensions to D dimensions. This method also suffers from limitation that one needs, in
+∗ bavarsad@kashanu.ac.ir
+
+2
+principle, to solve the field equations exactly. Another often used regularization procedure is point-splitting technique
+[15–18] which is intrinsically designed to be used in the position-space representation of the composite operators.
+This regularization is implemented by placing the two quantum fields at distant points separated by an infinitesimal
+distance in a nonnull direction and then the divergencies that arise in the coincidence limit are absorbed into the
+renormalized parameters. Although point-splitting technique is the most applicable regularization scheme, it involves
+considerable technical complication. An alternative regularization prescription is adiabatic subtraction [19–23] which
+was originally invented by Parker [5] to obtain the average density of the scalar particles created in a spatially flat
+Friedmann-Lemaitre-Robertson-Walker (FLRW) universe. This approach is only applicable in spacetimes with slowly
+varying curvature, and in fact an adiabatic expansion is an expansion in number derivatives of the spacetime metric.
+Hence, it is especially useful for studies that involve numerical techniques and problems of cosmological interest
+[22]. In order to arrive a sensible semiclassical backreaction theory of quantum fields in curved spacetime, Wald has
+propounded [24] a minimal set of properties that the renormalized energy-momentum tensor should satisfy. These
+properties which are often called the Wald axioms, in the weaker set of axioms, can be expressed as follows [1, 3]:
+(1) The expectation value of the energy-momentum tensor in any state at a point p in spacetime is covariant under
+general coordinate transformations (diffeomorphisms) and is independent of spacetime geometry at any point q ̸= p.
+(2) The off-diagonal matrix element of energy-momentum tensor between any orthogonal pairs of states is finite and
+unambiguous. (3) For all states, the expectation value of the energy-momentum tensor is covariantly conserved.
+(4) The expectation value of the energy-momentum tensor vanishes in the relevant vacuum state in the Minkowski
+spacetime. It was shown in [18] that the fifth axiom of Ref. [24] cannot be satisfied. Wald then proved a remarkable
+result, i.e., the uniqueness theorem, which states that if the expectation value of the energy-momentum tensor satisfies
+the Wald axioms (1)-(3), then it is unique up to the addition of a local conserved tensor [24]. Hence, the final results
+for the renormalized energy-momentum tensor do not depend on the employed regularization method [1, 3]. Using
+these regularization techniques, the regularized and renormalized energy-momentum tensor of a neutral scalar field
+has been widely investigated in FLRW universes [19–22, 25–33] and its physical implications for cosmological issues
+have been explored [34–36].
+It is thought that the very early universe can be approximately described by de Sitter spacetime (dS) [2], which
+motivates us to study the quantum field theory in this spacetime. Gibbons and Hawking [37] originally discovered
+that an inertial observer with a particle detector at rest perceives the de Sitter invariant vacuum state as a bath of
+thermal radiation which apparently comes from the cosmological event horizon. In this context, a relatively simple
+model problem is that of a neutral scalar field with no self-interactions whose regularized and renormalized energy-
+momentum tensor has been analyzed [11, 38–45]. In [39–41], it was subsequently shown that the vacuum state of the
+quantum field in dS is unstable to particle creation. Furthermore, the study of semiclassical backreaction effect of
+the quantum corrections onto the Hubble rate in [42] indicated that these contributions can potentially result in a
+superacceleration phase, i.e., a phase when the Hubble rate increases as the dS expands. The spontaneous creation
+of pairs of charged particles from the vacuum by a strong electric field background in Minkowski spacetime is a
+well-known nonperturbative feature of quantum field theory [46–48]. Since the clearest version of this effect was
+worked out by Schwinger, it is named the Schwinger effect; reviews of this subject can be found in, e.g., [49, 50]. The
+phenomenon of particle creation has revealed the close analogy between quantum field theory in dS and a constant,
+uniform electric field in Minkowski spacetime [40, 41, 51, 52]. This analogy motivates us to explore the combined
+implications of the dS Gibbons-Hawking effect and the Schwinger effect. Aside from this analogy, there are arguments
+and evidences that require the existence of strong electromagnetic fields in the early universe [53, 54]. This logical
+possibility provides a further reason for studying quantum field theory in the presence of an electric field in dS.
+There has been numerous studies to investigate the Schwinger pair creation by a uniform electric field background
+with the constant energy density in a dS. Seminal contributions have been made by [55, 56].
+The Bogoliubov
+transformation method has been used to analyze the Schwinger effect for the charged scalar field in two- [55–60],
+four- [61], and arbitrary-dimensional [62] de Sitter spacetimes. The Bogoliubov transformation method has been
+used to investigate the Schwinger effect for the Dirac field in dS [63–67], in a manner similar to that used for the
+corresponding charged scalar field. In this method of analysis, which bring its own insights, the expectation value for
+the number of particles is related to the Bogoliubov coefficients which, in turn, can be determined by specifying the
+in-vacuum and out-vacuum states. A reasonable definition of the out-vacuum state requires that the parameters mass
+of the quantum field and the electric field strength to satisfy the semiclassical condition. For a created semiclassical
+particle, this condition implies that either or both the mass and the magnitude of its electric potential energy acroses
+one Hubble radius must be much greater than the energy scale determined by the spacetime curvature [60, 61]. An
+immediate consequence of the semiclassical condition is that the entire physical ranges of the parameters mass and
+electric field strength cannot be probed by this method. A useful alternative approach for studying the Schwinger
+effect in dS was introduced in Ref. [60]. In this approach the expectation values of the objects such as the electric
+current and the energy-momentum tensor of the quantum field in the in-vacuum state are investigated. The choose
+of the in-state as the vacuum is justified form various viewpoints; see [55]. Regarding the regularity properties, it is a
+
+3
+Hadamard and adiabatic state [56, 60]. The regularized expectation value of the electric current (also called induced
+current) in the in-vacuum state of the charged scalar field coupled to a constant, uniform electric field background
+has been evaluated in two- [60], three- [62], and four-dimensional [61, 68] de Sitter spacetimes. In those analyses the
+behavior of the induced current can be probed in the infrared regime for which the quantum field mass is smaller than
+the magnitude of the electric potential energy acroses one Hubble radius which in turn is smaller than the energy scale
+determined by the spacetime curvature. The authors found that, although the induced current has been computed
+using different regularization method, in the infrared regime the induced current increases with deceasing electric field
+strength [60–62, 68]. This peculiar behavior was first observed in [60] and is called the infrared hyperconductivity. In
+[69], the authors gave an alternative derivation of the infrared hyperconductivity phenomenon in dS4 using the uniform
+asymptotic approximation method. For a charged scalar field coupled to a uniform electromagnetic field background
+with a constant energy density electric field parallel to a conserved flux magnetic field in dS4, the Schwinger effect
+using Bogoliubov transformation method [70–72] and the induced current [70, 71] in the in-vacuum state have been
+investigated; and a period of infrared hyperconductivity was found. The in-vacuum induced current of the Dirac field
+coupled to a constant, uniform electric field background in two- [65] and four-dimensional [73] de Sitter spacetimes
+has been analyzed in a manner similar to that used for the corresponding scalar field. It was subsequently found that,
+in contrast to the case of corresponding scalar field, the infrared hyperconductivity phenomenon does not occur in the
+induced current of the Dirac field. Another peculiar behavior of the induced current occurs when the direction of the
+induced current is opposite the direction of applied electric field background. This phenomenon which is called the
+negative current, has been reported for both the scalar field [61, 68] with essentially small mass and the Dirac field
+[73] with any mass in the four-dimensional de Sitter spacetime. For the scalar field case the negative current occurs in
+a finite interval of the electric field strength, and for the Dirac field case it occurs below a certain value of the electric
+field strength which depends on the mass. In Refs. [74, 75], some notable attempts have been made to explain and
+remedy these peculiarities of the induced current. Beside the induced current, the regularized expectation value of the
+energy-momentum tensor (also called the induced energy-momentum tensor) in the in-vacuum state of the charged
+scalar [76–78] and Dirac [79] quantum fields coupled to a constant, uniform electric field background has been analyzed
+in different dimensions of dS. In two-dimensional dS, the induced energy-momentum tensor of the charged scalar field
+has been analyzed in [76], and subsequently the nonperturbative, regularized, one-loop effective Lagrangian of scalar
+QED has been constructed; the induced energy-momentum tensor of the corresponding Dirac field has been derived
+in [79], and then applied to study of the gravitational backreaction effect. The trace of the induced energy-momentum
+tensor of the charged, massive scalar field conformally coupled to the Ricci scalar curvature of three- [77] and four-
+dimensional [78] de Sitter spacetimes has been computed; and to examine the evolution of the Hubble constant, the
+induced energy-momentum tensor has been obtained from the trace, along with the assumption that the created pairs
+act like a perfect fluid with a vacuum equation of state. By applying the Bogoliubov transformation method, the
+energy-momentum tensor of the Schwinger scalar pairs created by a constant, uniform electric field background in an
+arbitrary dimensional dS has been computed under the two limiting conditions, i.e., the heavy scalar field [62] and
+the strong electric field [80]. In both these cases, it was found that the Hubble constant decays as a consequence
+of the Schwinger pair creation. Before closing the present section, it is worthwhile to mention that the Schwinger
+effect has been studied in FLRW spacetimes [81] and in the framework of cosmological models [69, 82–92]. The role
+of strong electromagnetic fields in astrophysics and cosmology was reviewed in [93]. The objectives of this article
+are to investigate the induced energy-momentum tensor of the charged scalar field coupled to a uniform electric field
+background in dS4, and to analyze its nonconservation equation. The importance and originality of this study are that
+it calculates the induced energy-momentum tensor and explores a relation between the induced energy-momentum
+tensor and the induced current which leads to new insights into the regularization and behavior of the induced current.
+The remaining part of the article proceeds as follows: In Sec. II, we define and construct the basic elements of
+the formalism that will be necessary in our subsequent discussions. We then carry out explicit computation of the
+induced energy-momentum tensor in Sec. III. The properties of the induced energy-momentum tensor are explored
+in detail in Sec. IV. In Sec. V, we analyze the nonconservation equation of the induced energy-momentum tensor,
+this investigation yields a relation between the induced energy-momentum tensor and the induced current. Then the
+properties of the resulting induced current are discussed in detail. In Sec. VI, we present the findings of the research.
+In the Appendix we present further supplementary data associated with the calculation of the expectation values of
+the components of the energy-momentum tensor.
+II.
+BASIC DEFINITIONS AND CONSTRUCTIONS
+In this section we shall define and construct the basic elements of the formalism that will be necessary in our
+subsequent discussions.
+
+4
+A.
+Specification of the model
+We have already mentioned that we consider a massive complex scalar field ϕ(x), coupled to the electromagnetic
+vector potential Aµ(x), which describes a uniform electric field background with a constant energy density in the
+conformal Poincar´e patch of dS4. To represent this region of dS4 which is conformally related to a region of Minkowski
+spacetime, we choose the coordinates xµ = (τ, x) that the ranges of the conformal time τ, and the comoving spatial
+coordinates x are given by
+τ ∈
+�
+− ∞, 0
+�
+,
+x ∈ R3.
+(1)
+In terms of these coordinates the metric of the spacetime takes the form
+gµνdxµdxν = Ω2(τ)
+�
+dτ 2 − dx · dx
+�
+,
+(2)
+with the conformal scale factor
+Ω(τ) = − 1
+Hτ ,
+(3)
+where H is the Hubble constant. The nonzero Christoffel symbols for the metric (2) are given by
+Γ0
+00 =
+˙Ω
+Ω,
+Γ0
+ij =
+˙Ω
+Ωδij,
+Γi
+0j =
+˙Ω
+Ωδi
+j,
+(4)
+where the roman indices i, j denote only three spatial components and run from 1 to 3. We use the overdot to denote
+differentiation with respect to the conformal time τ. From Eq. (4) the Ricci tensor and hence the Ricci scalar can be
+calculated
+Rµν = 3H2gµν,
+R = 12H2.
+(5)
+We put a uniform electric field background with a constant energy density on the Poincar´e patch represented in
+Eq. (2). Without loss of generality, we choose our coordinates so that this electric field to point in the x1 direction.
+Thus the nonzero components of the electromagnetic field tensor are
+F01 = −F10 = Ω2(τ)E,
+(6)
+where E is a constant. It is convenient to express this electromagnetic field tensor in terms of a vector potential in
+the Coulomb gauge [60–62] as
+Aµ(τ) = − E
+H2τ δ1
+µ.
+(7)
+The compleat action Stot of this theory can be represented as sum of a pure gravitational piece, an electromagnetic
+piece, and a scalar field piece
+Stot = Sgr + Sem + S.
+(8)
+Here Sgr is the Einstein-Hilbert action that only includes the gravitation piece of the compleat action, and is given by
+Sgr =
+1
+16πG
+�
+d4x√−g
+�
+R − 2Λc
+�
+,
+(9)
+where G is Newton’s gravitational constant, g is the determinant of the metric, R is the Ricci scalar of the spacetime,
+and Λc is the cosmological constant. The electromagnetic piece of the compleat action is expressed in terms of the
+electromagnetic field tensor as
+Sem = −1
+4
+�
+d4x√−gFµνF µν.
+(10)
+The dynamics of the complex scalar field ϕ(x) of mass m coupled to the electromagnetic vector potential (7) with
+coupling e is governed by the last piece of the compleat action which can be written as
+S =
+�
+d4x√−g
+�
+gµν�
+∂µ + ieAµ
+�
+ϕ
+�
+∂ν − ieAν
+�
+ϕ∗ − (m2 + ξR)ϕϕ∗�
+,
+(11)
+
+5
+where ξ is a dimensionless nonminimal coupling constant which describes the strength of the coupling ϕ to the Ricci
+scalar (5). The Euler-Lagrange equations of motion give the Klein-Gordon equation for the scalar field
+1
+√−g ∂µ
+�√−ggµν∂νϕ
+�
++ 2iegµνAµ∂νϕ − e2gµνAµAνϕ + (m2 + ξR)ϕ = 0,
+(12)
+and the Maxwell equation for the electromagnetic field
+∇νF νµ = jµ,
+(13)
+where ∇ denotes the covariant derivative operator, and jµ is the electric current of the scalar field caused by the
+electric field background (6) which is defined by
+jµ(x) = iegµν��
+∂νϕ + ieAνϕ
+�
+ϕ∗ − ϕ
+�
+∂νϕ∗ − ieAνϕ∗��
+.
+(14)
+It is straightforward to verify that ∇µjµ = 0, i.e., the electric current is conserved.
+B.
+Preliminary definition of the energy-momentum tensor
+The classical Einstein equation can be derived from the compleat action (8) by demanding the invariance of Stot
+under infinitesimal variation of the metric δgµν, or equivalently, infinitesimal variation of the inverse metric δgµν.
+This condition requires that
+2
+√−g
+δStot
+δgµν =
+2
+√−g
+� δSgr
+δgµν + δSem
+δgµν + δS
+δgµν
+�
+= 0.
+(15)
+The Variation of expression (9) with respect to δgµν leads to
+2
+√−g
+δSgr
+δgµν =
+1
+8πG
+�
+Rµν − 1
+2Rgµν + Λcgµν
+�
+.
+(16)
+The variations of the electromagnetic action Sem, and the scalar field action S, with respect to δgµν define the
+energy-momentum tensor of the electromagnetic field T (em)
+µν
+, and the energy-momentum tensor of the scalar field Tµν,
+respectively, as
+2
+√−g
+δSem
+δgµν = T (em)
+µν
+,
+(17)
+2
+√−g
+δS
+δgµν = Tµν.
+(18)
+Plugging expressions (10) and (11) into Eqs. (17) and (18), respectively, and following the standard calculus of
+variations procedure yields the energy-momentum tensor of the electromagnetic field
+T (em)
+µν
+= 1
+4gµνFρσF ρσ + gρσFµρFσν,
+(19)
+and a preliminary expression for the energy-momentum tensor of the scalar field
+Tµν =
+��
+4ξ − 1
+�
+gρσ�
+∂ρ + ieAρ
+�
+ϕ
+�
+∂σ − ieAσ
+�
+ϕ∗ +
+�
+1 − 4ξ
+�
+m2ϕϕ∗ +
+�1
+2 − 4ξ
+�
+ξRϕϕ∗�
+gµν
++
+�
+1 − 2ξ
+��
+∂µϕ∂νϕ∗ + ∂νϕ∂µϕ∗�
++ ieAµ
+�
+ϕ∂νϕ∗ − ∂νϕϕ∗�
++ ieAν
+�
+ϕ∂µϕ∗ − ∂µϕϕ∗�
++ 2e2AµAνϕϕ∗ + 2ξΓρ
+µν
+�
+ϕ∂ρϕ∗ + ∂ρϕϕ∗�
+− 2ξ
+�
+∂µ∂νϕϕ∗ + ϕ∂µ∂νϕ∗�
+.
+(20)
+Plugging three expressions (16)-(18) into Eq. (15) gives the Einstein equation
+Rµν − 1
+2Rgµν + Λcgµν = −8πG
+�
+T (em)
+µν
++ Tµν
+�
+.
+(21)
+
+6
+An important property of the Einstein equation is that both sides of Eq. (21) have identically vanishing covariant
+divergences, which implies
+∇µT µν = −∇µT (em)µν.
+(22)
+Using the Klein-Gordon Eq. (12), it is straightforward to show that the covariant divergence of expression (20) is
+given by
+∇µT µν = −jµF µν,
+(23)
+Apparently, the energy-momentum tensor of the scalar field is not covariantly conserved in the presence of the
+electromagnetic field, as the consequence of the electromagnetic interactions. We show that the nonconservation of
+Tµν is compatible with the nonconservation of T (em)
+µν
+so that the relation (22) is satisfied, and hence the total energy
+momentum tensor is covariantly conserved. By taking the covariant divergence of the expression (19) and using the
+Maxwell equation (13), it is seen that
+∇µT (em)µν = jµF µν.
+(24)
+As a result of Eqs. (23) and (24), it is evident that the relation (22) is satisfied. Hence, the total energy-momentum
+tensor Tµν + T (em)
+µν
+is manifestly conserved.
+It will be important to state that we will treat the classical gravitational field (2) and the classical electromagnetic
+field (7) as fixed field configurations which they are unaffected by the dynamics of the quantum complex scalar field
+ϕ(x) in response to these backgrounds. In fact, the Einstein equation (21) describes the backreaction effects on the
+gravitational field, and the Maxwell equation (13) and Eq. (24) describe the backreaction effects on the electromagnetic
+field. Indeed, due to the conceptual importance of Eq. (23) in our subsequent discussions, we have presented Eqs. (13),
+(21), and (24) to provide a fairly detailed discussion of its derivation. It is then clear that we do not discuss these
+equations further in this article.
+C.
+Quantizing the complex scalar field
+Quantizing the complex scalar field ϕ(x), in the classical gravitational (2) and electromagnetic (7) field backgrounds
+is completely straightforward and follows exactly the same route as that of a complex scalar field in Minkowski
+spacetime. We will solve the Kline-Gordon Eq. (12), and then adopting canonical quantization method, we can define
+the in-vacuum state to obtain the expectation value of the energy-momentum tensor operator.
+Taking account of the fact that the gravitational (2) and electromagnetic (7) backgrounds are invariant under
+spatial translations, it is convenient to write the mode solution of Eq. (12) as
+Uk(x) = Ω−1(τ)eik·xf(τ),
+(25)
+where k is the comoving momentum. Plugging Eqs. (2), (7), and (25) into Eq. (12), we can put the differential
+equation in a standard form by the change of variable z = 2ikτ so that k = |k|. Then it becomes
+d2f
+dz2 +
+�
+− 1
+4 + κ
+z + 1/4 − γ2
+z2
+�
+f(z) = 0,
+(26)
+where the dimensionless parameters are defined through
+µ = m
+H ,
+λ = − eE
+H2 ,
+¯ξ = ξ − 1
+6,
+r = kx
+k ,
+κ = −iλr,
+γ =
+�
+1
+4 − λ2 − µ2 − 12¯ξ.
+(27)
+Two values of ξ are of particular interest that are the minimally coupled case ξ = 0, and conformally coupled
+case ξ = 1/6 which implies ¯ξ = 0. The variable kx which appears in the definition of the parameter r, denotes
+the component of the comoving momentum k along the electric field background. Equation (26) is the Whittaker
+equation, and the solutions are called Whittaker functions; see, e.g., [94]. We define the in-vacuum state |in⟩ so
+that in the remote past (τ → −∞) where the spacetime is asymptotically Minkowskian, an inertial observer there
+would identify this state with a physical vacuum. This vacuum state may be represented by a mode solution of the
+Whittaker Eq. (26) which behaves like a mode function in Minkowski spacetime in the limit of τ → −∞. Hence, the
+
+7
+solution of Eq. (26) with the desired asymptotic form in the limit of |z| → ∞ which can be represented in terms of a
+Mellin-Barnes integral [94] is
+Wκ,γ(z) =
+e− z
+2
+Γ
+� 1
+2 + γ − κ
+�
+Γ
+� 1
+2 − γ − κ
+�
+� +i∞
+−i∞
+ds
+2πiΓ
+�1
+2 + γ + s
+�
+Γ
+�1
+2 − γ + s
+�
+Γ
+�
+− κ − s
+�
+z−s,
+(28)
+with the condition that the phase of the variable z and the values of the parameters γ and κ must satisfy the following
+inequalities
+��ph(z)
+�� < 3π
+2 ,
+1
+2 ± γ − κ ̸= 0, −1, −2, · · · .
+(29)
+In expression (28), the factors denoted by Γ are the gamma functions. The contour of the Mellin-Barnes integral (28)
+consists of a straight vertical line from minus infinity to infinity, parallel to imaginary axis in the complex plane, and
+of a semicircle at infinity with indentations if necessary to avoid poles of the integrand in a way that separates the
+poles of Γ
+� 1
+2 + γ + s
+�
+and Γ
+� 1
+2 − γ + s
+�
+from the poles of Γ
+�
+− κ − s
+�
+. The normalized mode functions which behave
+like the positive frequency Minkowski mode functions in the remote past are given by [61, 62],
+Uk(x) =
+1
+√
+2k
+e
+iπκ
+2 Ω−1(τ)eik·xWκ,γ
+�
+2ikτ
+�
+.
+(30)
+Besides, the normalized mode functions which behave like the negative frequency Minkowski mode functions in the
+remote past are found to be [61, 62],
+Vk(x) =
+1
+√
+2k
+e− iπκ
+2 Ω−1(τ)e−ik·xWκ,γ
+�
+− 2ikτ
+�
+.
+(31)
+We have conventionally normalized the mode functions (30) and (31) such that their Wronskian to be
+Uk ˙U ∗
+k − U ∗
+k ˙Uk = V ∗
+k ˙Vk − Vk ˙V ∗
+k = iΩ−2(τ).
+(32)
+These mode functions will be orthonormal with respect to the conserved scalar product integrated over the constant
+τ hypersurface [62]. The usual canonical quantization will proceed by introducing the creation a†
+k, and annihilation
+ak operators for each of mode functions Uk, and similarly the creation b†
+k, and annihilation bk operators for each of
+mode functions Vk. The creation and annihilation operators satisfy the commutation rules
+�
+ak, a†
+k′
+�
+=
+�
+bk, b†
+k′
+�
+= (2π)3δ
+�
+k − k′�
+,
+(33)
+with all other commutators vanishing. Then, the complex scalar field operator can be expanded in terms of the
+creation and annihilation operators in the standard manner as
+ϕ(x) =
+�
+d3k
+(2π)3
+�
+akUk(x) + b†
+kVk(x)
+�
+.
+(34)
+The in-vacuum state |in⟩ is characterized by the fact that it is annihilated by each of ak and bk operators
+ak
+��in
+�
+= bk
+��in
+�
+= 0,
+∀k.
+(35)
+III.
+CONSTRUCTION OF THE INDUCED ENERGY-MOMENTUM TENSOR
+Having built a foundation for our discussion and presented the definition for the energy-momentum tensor of the
+scalar field in Eq. (20), we will proceed to present the regularized in-vacuum expectation value of the energy-momentum
+tensor of the scalar field.
+A.
+Unregularized expectation values in the in-vacuum state
+Integral representations for the in-vacuum expectation values of the components of the energy-momentum tensor
+can be obtained by substituting the mode expansion (34) for the quantum scalar field ϕ(x) into the definition (20),
+
+8
+and then calculating the expectation values in the in-vacuum state using relations (33) and (35). By using Eq. (12)
+and some algebra, we have the following integral expressions in terms of the positive frequency mode function (30)
+for the expectation values of the components. The integral expression of the timelike component is given by
+�
+in
+��T00
+��in
+�
+=
+�
+d3k
+(2π)3
+�
+˙Uk ˙U ∗
+k − 6ξτ −1�
+Uk ˙U ∗
+k + ˙UkU ∗
+k
+�
++ τ −2�
+k2τ 2 + 2λrkτ + λ2 + µ2 + 6ξ
+�
+UkU ∗
+k
+�
+.
+(36)
+For the diagonal spacelike components we get
+�
+in
+��T11
+��in
+�
+=
+�
+d3k
+(2π)3
+��
+1 − 4ξ
+� ˙Uk ˙U ∗
+k − 2ξτ −1�
+Uk ˙U ∗
+k + ˙UkU ∗
+k
+�
++ τ −2��
+4ξ − 1 + 2r2�
+k2τ 2 + 2
+�
+4ξ + 1
+�
+λrkτ
++
+�
+4ξ + 1
+�
+λ2 +
+�
+4ξ − 1
+�
+µ2 + 6ξ
+�
+8ξ − 1
+��
+UkU ∗
+k
+�
+,
+(37)
+and
+�
+in
+��T22
+��in
+�
+=
+�
+in
+��T33
+��in
+�
+=
+�
+d3k
+(2π)3
+��
+1 − 4ξ
+� ˙Uk ˙U ∗
+k − 2ξτ −1�
+Uk ˙U ∗
+k + ˙UkU ∗
+k
+�
++ τ−2��
+4ξ − 1
+�
+k2τ 2
++ 2k2
+zτ 2 + 2
+�
+4ξ − 1
+�
+λrkτ +
+�
+4ξ − 1
+�
+λ2 +
+�
+4ξ − 1
+�
+µ2 + 6ξ
+�
+8ξ − 1
+��
+UkU ∗
+k
+�
+.
+(38)
+The only nonvanishing in-vacuum expectation values of the off-diagonal components can be expressed as
+�
+in
+��T01
+��in
+�
+=
+�
+in
+��T10
+��in
+�
+= iτ −1
+�
+d3k
+(2π)3
+�
+rkτ + λ
+��
+Uk ˙U ∗
+k − ˙UkU ∗
+k
+�
+.
+(39)
+Using the asymptotic expansion of the Whittaker function (28) for large values of its argument [94], it can be shown
+that the mode function (30) is proportional to k− 1
+2 −iλr in the limit of k → ∞. Then, inspection of integrals in
+Eqs. (36)-(39) shows that these expressions are ultraviolet divergent. Thus, we first regulate them by cutting them
+of at a large momentum K. Further description of the calculation of the expressions (36)-(38) is available in the
+Appendix. We find the final expression for the unregularized in-vacuum expectation value of the timelike component
+�
+in
+��T00
+��in
+�
+= Ω2(τ) H4
+8π2
+�
+Λ4 +
+�
+µ2 − 6¯ξ + 2λ2
+3
+�
+Λ2 −
+�µ4
+2 + 6¯ξµ2 − λ2
+6
+�
+log
+�
+2Λ
+�
++ 54¯ξ2 − 2λ4
+15 + µ2
+4 + 6¯ξµ2 + µ4
+8
+− 19λ2
+72
+− 2λ2¯ξ − λ2µ2
+2
++
+γ
+24π
+�45
+π2 − 6 − 96¯ξ + 4λ2 − 26µ2
+�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+� −
+γ
+48π2λ
+� 45
+π2 − 6 − 96¯ξ + 64λ2 − 26µ2
+�
+× sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+� + i csc
+�
+2πγ
+� � +1
+−1
+C0r
+��
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr
++ iπ
+12
+�
+3µ4 + 36¯ξµ2 − λ2��
+,
+(40)
+where the coefficient C0r is given by
+C0r = −5
+8λ4r4 + 1
+8
+�
+6µ2 + 6λ2 + 36¯ξ + 1
+�
+λ2r2 − 1
+8
+�
+µ2 + λ2��
+µ2 + λ2 + 12¯ξ
+�
+.
+(41)
+The final results of our evaluation of the unregularized in-vacuum expectation values of the diagonal spacelike com-
+ponents are
+�
+in
+��T11
+��in
+�
+= Ω2(τ) H4
+8π2
+�Λ4
+3 +
+�
+2¯ξ − µ2
+3 + 14λ2
+15
+�
+Λ2 +
+�µ4
+2 + 6¯ξµ2 − λ2
+6
+�
+log
+�
+2Λ
+�
+− 54¯ξ2 − 26λ4
+105 − 7µ4
+24 − 8¯ξµ2
+− 18¯ξ
+5 λ2 − µ2
+4 + 19λ2
+72
++ λ2µ2
+30
+−
+γ
+24πλ2
+�15
+π2
+�
+105π−2 − 15 − 132¯ξ + 35λ2 − 11µ2�
+− 66λ2 − 336¯ξλ2 − 4λ4
+− 46λ2µ2
+�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+� +
+γ
+48π2λ3
+�15
+π2
+�
+105π−2 − 15 − 132¯ξ + 175λ2 − 11µ2�
+− 366λ2 − 2976¯ξλ2 + 136λ4
+− 266λ2µ2
+�sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+� + i csc
+�
+2πγ
+� � +1
+−1
+C1r
+��
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr − iπ
+12
+�
+3µ4 + 36¯ξµ2 − λ2��
+,
+(42)
+
+9
+where the coefficient C1r is given by
+C1r = 35
+8 λ4r6 − 1
+8
+�
+70λ4 + 30λ2µ2 + 360¯ξλ2 + 25λ2�
+r4 + 1
+8
+�
+39λ4 + 3µ4 + 30λ2µ2 + 396¯ξλ2 + 72¯ξµ2 + 20λ2
++ 6µ2 + 432¯ξ2 + 72¯ξ
+�
+r2 − 1
+8
+�
+4λ4 + 4λ2µ2 + 60¯ξλ2 + 12¯ξµ2 + 2λ2 + 2µ2 + 144¯ξ2 + 24¯ξ
+�
+,
+(43)
+we also have
+�
+in
+��T22
+��in
+�
+=
+�
+in
+��T33
+��in
+�
+= Ω2(τ) H4
+8π2
+�Λ4
+3 +
+�
+2¯ξ − µ2
+3 − 2λ2
+15
+�
+Λ2 +
+�µ4
+2 + 6¯ξµ2 + λ2
+6
+�
+log
+�
+2Λ
+�
+− 54¯ξ2 + 2λ4
+35
+− 7µ4
+24 − 8¯ξµ2 + 4¯ξ
+5 λ2 − µ2
+4 − 19λ2
+72
++ 2
+5λ2µ2 +
+γ
+16πλ2
+� 5
+π2
+�
+105π−2 − 15 − 132¯ξ + 38λ2 − 11µ2�
+− 24λ2
+− 144¯ξλ2
+�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+� −
+γ
+32π2λ3
+� 5
+π2
+�
+105π−2 − 15 − 132¯ξ + 178λ2 − 11µ2�
+− 124λ2 − 1024¯ξλ2 + 200λ4
+3
+− 220
+3 λ2µ2
+�sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+� + i csc
+�
+2πγ
+� � +1
+−1
+C2r
+��
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr − iπ
+12
+�
+3µ4 + 36¯ξµ2 + λ2��
+,
+(44)
+where the coefficient C2r is given by
+C2r = −C1r
+2
+− 5
+16λ4r4 + 1
+16
+�
+6λ2 − 6µ2 + 36¯ξ + 1
+�
+λ2r2 + 1
+16
+�
+3µ4 + 2λ2µ2 + 12¯ξλ2 + 36¯ξµ2 − λ2�
+.
+(45)
+Plugging the resulting expression given in Eq. (32) for the Wronskian of the mode functions Uk into Eq. (39) and
+integrating over momentum phase space, we obtain the unregularized expression for the only nonvanishing off-diagonal
+components
+�
+in
+��T01
+��in
+�
+=
+�
+in
+��T10
+��in
+�
+= Ω2(τ)H4λ
+6π2 Λ3.
+(46)
+The expressions (40), (42), (44), and (46) clearly have ultraviolet divergences when Λ → ∞. This was expected,
+because the expectation values in the Hadamard in-vacuum state suffer from the same ultraviolet divergence properties
+as Minkowski spacetime.
+B.
+Construction of the counterterms and adiabatic subtractions
+To render the in-vacuum expectation values given by Eqs. (40), (42), (44), and (46) finite, we provide a set of
+needed adiabatic counterterms. The adiabatic regularization method consists of subtracting the appropriate adiabatic
+counterterms from the corresponding unregularized expressions. To adjust the set of appropriate counterterms, we will
+treat the conformal scale factor Ω(τ), and the electromagnetic vector potential Aµ(τ) as quantities of zero adiabatic
+order. As pointed out by Wald [18], in four dimensions, to obtain a renormalized energy-momentum tensor which
+is consistent with the Wald axioms, the subtraction counterterms should be expanded up to fourth adiabatic order;
+see also [1, 2]. Thus, to construct the expectation value of the energy-momentum tensor with the desired physical
+properties, we expand the subtraction counterterms up to fourth adiabatic order.
+To construct the appropriate
+counterterms, we need an expansion for the mode functions up to fourth adiabatic order. We use the definition
+z = 2ikτ to turn the Klein-Gordon Eq. (26) into the convenient form
+d2FA
+dτ 2
++
+�
+ω2
+0(τ) + ∆(τ)
+�
+FA = 0,
+(47)
+where FA is the positive frequency adiabatic solution and the conformal time dependent frequencies read
+ω0(τ) =
+�
+k2 + 2eA1kr + e2A2
+1 + m2Ω2� 1
+2 ,
+(48)
+∆(τ) = 12¯ξ
+� ˙Ω
+Ω
+�2
+.
+(49)
+
+10
+It is then obvious that ω0 is of zero adiabatic order and ∆ is of second adiabatic order. The adiabatic form of FA is
+the Wentzel-Kramers-Brillouin (WKB) solution of Eq. (47). This WKB solution can be written as
+FA(τ) =
+1
+�
+2W(τ)
+exp
+�
+− i
+� τ
+W(τ ′)dτ ′�
+,
+(50)
+where W satisfies the exact equation
+W2 = ω2
+0 + ∆ −
+¨
+W
+2W + 3 ˙W2
+4W2 .
+(51)
+To put the solution into the desired form, it is convenient to write W as
+W = W(0) + W(2) + W(4),
+(52)
+where the superscript numbers in parentheses denote the adiabatic order approximation to W.
+Substituting the
+expansion (52) into Eq. (51), we find the zero adiabatic order approximation
+W(0) = ω0.
+(53)
+The next iteration gives the second adiabatic order approximation
+W(2) = ∆
+2ω0
+− ¨ω0
+4ω2
+0
++ 3 ˙ω2
+0
+8ω3
+0
+.
+(54)
+Repeated iteration yields the fourth adiabatic order approximation
+W(4) = −W(2)2
+2ω0
+−
+¨
+W(2)
+4ω2
+0
++ ¨ω0W(2)
+4ω3
+0
++ 3 ˙ω0 ˙W(2)
+4ω3
+0
+− 3 ˙ω2
+0W(2)
+4ω4
+0
+.
+(55)
+It should be remarked that all terms in the adiabatic expansion of W of odd adiabatic order vanish. Assembling the
+pieces given in Eqs. (25), (50), and (52)-(55), we find the positive frequency adiabatic solution to fourth adiabatic
+order approximation
+U [4]
+k (x) = Ω−1(τ)
+1
+√2ω0
+�
+1 − W(2)
+2ω0
+− W(4)
+2ω0
++ W(2)2
+2ω2
+0
+�
+exp
+�
+ik · x − i
+� τ
+W(τ ′)dτ ′�
+.
+(56)
+We use the superscript symbol [4] to indicate that the cross terms from the field expansion products that are of
+adiabatic order greater than 4 are to be discarded. To obtain expansions of the required counterterms to adiabatic
+order four, it is only necessary to calculate (36)-(39) with Uk replaced by U [4]
+k . Doing this, we find the counterterm
+to adiabatic order four for the timelike component
+T [4]
+00 = Ω2(τ) H4
+8π2
+�
+Λ4 +
+�
+µ2 − 6¯ξ + 2λ2
+3
+�
+Λ2 −
+�µ4
+2 + 6¯ξµ2 − λ2
+6
+�
+log
+�2Λ
+µ
+�
++ 72¯ξ2 − λ4
+15 + µ2
+6 + 9¯ξµ2 + µ4
+8
+− 2λ2
+9
+− 2λ2 ¯ξ − λ2µ2
+3
+− 1
+60 +
+7λ4
+240µ4 +
+λ2
+30µ2 − 3¯ξλ2
+2µ2
+�
+.
+(57)
+We find the counterterms to adiabatic order four for the diagonal spacelike components
+T [4]
+11 = Ω2(τ) H4
+8π2
+�Λ4
+3 +
+�
+2¯ξ − µ2
+3 + 14λ2
+15
+�
+Λ2 +
+�µ4
+2 + 6¯ξµ2 − λ2
+6
+�
+log
+�2Λ
+µ
+�
+− 72¯ξ2 − 13λ4
+105 − 7µ4
+24 − 11¯ξµ2
+− 14¯ξ
+5 λ2 − µ2
+6 + 7λ2
+18 − λ2µ2
+15
++ 1
+60 −
+7λ4
+240µ4 +
+λ2
+18µ2 + 3¯ξλ2
+2µ2
+�
+,
+(58)
+and
+T [4]
+22 = T [4]
+33 = Ω2(τ) H4
+8π2
+�Λ4
+3 +
+�
+2¯ξ − µ2
+3 − 2λ2
+15
+�
+Λ2 +
+�µ4
+2 + 6¯ξµ2 + λ2
+6
+�
+log
+�2Λ
+µ
+�
+− 72¯ξ2 + λ4
+35
+− 7µ4
+24 − 11¯ξµ2 + 2¯ξ
+5 λ2 − µ2
+6 − 7λ2
+18 + λ2µ2
+5
++ 1
+60 +
+7λ4
+720µ4 −
+λ2
+45µ2 −
+¯ξλ2
+2µ2
+�
+.
+(59)
+
+11
+We obtain the counterterms to adiabatic order four for the only nonvanishing off-diagonal components
+T [4]
+01 = T [4]
+10 = Ω2(τ)H4λ
+6π2 Λ3.
+(60)
+Then, the adiabatic regularization procedure is carried out by subtracting the counterterms (57)-(60) from the corre-
+sponding unregularized in-vacuum expectation values (40), (42), (44), and (46). Thus we obtain our final expression
+for the timelike component of the regularized energy-momentum tensor
+T00 =
+�
+in
+��T00
+��in
+�
+− T [4]
+00
+= Ω2(τ) H4
+8π2
+� 1
+60 −
+7λ4
+240µ4 −
+λ2
+30µ2 + 3¯ξλ2
+2µ2 − 18¯ξ2 − λ4
+15 + µ2
+12 − 3¯ξµ2 − λ2
+24 − λ2µ2
+6
++
+γ
+24π
+�45
+π2 − 6 − 96¯ξ + 4λ2 − 26µ2
+�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+� −
+γ
+48π2λ
+�45
+π2 − 6 − 96¯ξ + 64λ2 − 26µ2
+�sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+�
++ i csc
+�
+2πγ
+� � +1
+−1
+C0r
+��
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr
+−
+�µ4
+2 + 6¯ξµ2 − λ2
+6
+�
+log
+�
+µ
+�
++ iπ
+12
+�
+3µ4 + 36¯ξµ2 − λ2��
+.
+(61)
+We obtain our final expressions for the diagonal spacelike components of the regularized energy-momentum tensor
+T11 =
+�
+in
+��T11
+��in
+�
+− T [4]
+11
+= Ω2(τ) H4
+8π2
+�
+− 1
+60 +
+7λ4
+240µ4 −
+λ2
+18µ2 − 3¯ξλ2
+2µ2 + 18¯ξ2 − 13λ4
+105 + 3¯ξµ2 − 4¯ξλ2
+5
+− µ2
+12 − λ2
+8 + λ2µ2
+10
+−
+γ
+24πλ2
+�15
+π2
+�
+105π−2 − 15 − 132¯ξ + 35λ2 − 11µ2�
+− 66λ2 − 336¯ξλ2 − 4λ4 − 46λ2µ2
+�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+�
++
+γ
+48π2λ3
+� 15
+π2
+�
+105π−2 − 15 − 132¯ξ + 175λ2 − 11µ2�
+− 366λ2 − 2976¯ξλ2 + 136λ4 − 266λ2µ2
+�sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+�
++ i csc
+�
+2πγ
+� � +1
+−1
+C1r
+��
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr
++
+�µ4
+2 + 6¯ξµ2 − λ2
+6
+�
+log
+�
+µ
+�
+− iπ
+12
+�
+3µ4 + 36¯ξµ2 − λ2��
+,
+(62)
+and
+T22 = T33 =
+�
+in
+��T33
+��in
+�
+− T [4]
+33
+= Ω2(τ) H4
+8π2
+�
+− 1
+60 −
+7λ4
+720µ4 +
+λ2
+45µ2 +
+¯ξλ2
+2µ2 + 18¯ξ2 + λ4
+35 + 3¯ξµ2 + 2¯ξλ2
+5
+− µ2
+12 + λ2
+8 + λ2µ2
+5
++
+γ
+16πλ2
+� 5
+π2
+�
+105π−2 − 15 − 132¯ξ + 38λ2 − 11µ2�
+− 24λ2 − 144¯ξλ2
+�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+�
+−
+γ
+32π2λ3
+� 5
+π2
+�
+105π−2 − 15 − 132¯ξ + 178λ2 − 11µ2�
+− 124λ2 − 1024¯ξλ2 + 200λ4
+3
+− 220
+3 λ2µ2
+�sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+�
++ i csc
+�
+2πγ
+� � +1
+−1
+C2r
+��
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr
++
+�µ4
+2 + 6¯ξµ2 + λ2
+6
+�
+log
+�
+µ
+�
+− iπ
+12
+�
+3µ4 + 36¯ξµ2 + λ2��
+.
+(63)
+We see that the nonvanishing unregularized expectation values of the off-diagonal components, given by Eq. (46), are
+exactly cancelled by their counterterms (60),
+T01 = T10 =
+�
+in
+��T10
+��in
+�
+− T [4]
+10 = 0.
+(64)
+Thus we have arrived at the desired expressions for the regularized in-vacuum expectation values of all the components
+of the energy-momentum tensor, also called the induced energy-momentum tensor.
+
+12
+0.01
+10
+104
+107
+10-8
+100
+1012
+1022
+1032
+1042
+�
+|T0
+0|/H4
+�=0.01
+�=0.1
+�=1
+�=10
+�=100
+ξ=0
+ξ=
+1
+6
+FIG. 1. The absolute value of T 0
+0 component of the induced energy-momentum tensor is plotted in unit of H4 as a function of
+the electric field parameter λ = −eE/H2. The graphs correspond to different values of the mass parameter µ = m/H, and the
+coupling constant ξ as indicated. Both axes have logarithmic scales.
+IV.
+PROBING THE INDUCED ENERGY-MOMENTUM TENSOR
+The nonvanishing components of the induced energy-momentum tensor are given by Eqs. (61)-(63). Observe that
+all the off-diagonal components of the induced energy-momentum tensor are zero, and the components T22 and T33 are
+equal as consequences of the underlying symmetries of the backgrounds (2) and (6). Furthermore, since the electric
+field background (6) is not invariant under full symmetries of de Sitter spacetime, indeed violates the time reversal
+symmetry [51], and causes an electric current along its direction, we observe that T00, T11, and T22 are not equal
+to one another. Thus we expect that in the limit of vanishing electric field background that the in-vacuum state
+possesses the full set of de Sitter invariances, the induced energy-momentum tensor takes the maximally invariant
+form under the transformations of de Sitter group, i.e., must be proportional to the de Sitter metric. By setting λ = 0
+in Eqs. (61)-(63), which corresponds to vanishing electric field background, the induced energy-momentum tensor
+reduced to the form
+Tµν = H4
+32π2
+� 1
+15 − 72¯ξ2 − 12¯ξµ2 − 2µ2
+3
++ µ2�
+12¯ξ + µ2��
+ψ
+�3
+2 + γ0
+�
++ ψ
+�3
+2 − γ0
+�
+− log
+�
+µ2���
+gµν,
+(65)
+where γ0 =
+�
+(1/4) − µ2 − 12¯ξ is obtained by setting λ = 0 in the definition of γ. The expression (65) accords with
+the result of computing the renormalized vacuum energy-momentum tensor of a real scalar field in dS4 obtained in
+Refs. [11, 38], except for the overall factor of 2 in Eq. (65). This factor 2 is consistent with the complex scalar field
+as being made of two real scalar fields with the number of degrees of freedom doubling up.
+A.
+Behavior of the induced energy-momentum tensor
+Figures 1-3 provide some useful insight into the general behavior of the induced energy-momentum tensor. The
+absolute values of the expressions (61)-(63) as functions of the electric field parameter λ, for various values of the scalar
+field mass parameter µ, and two values of the coupling constant ξ are shown on the graphs in Figs. 1-3, respectively.
+Note especially that the scales are logarithmic on both axes, hence on the graphs zero values of the expressions, where
+the signs of the plots change, are displayed as singularities. Therefore, these figures signal that the induced energy-
+momentum tensor is analytic and varies continuously with the parameters λ, µ, and ξ, this statement consistent with
+the requirements discussed in [95]. Figures 1-3 also illustrate the outstanding qualitative features of the induced
+energy-momentum tensor. For fixed values of µ and ξ, the absolute values of the nonvanishing components of induced
+energy-momentum tensor are increasing functions of λ, but by excluding a neighbourhood of the zero value points this
+
+13
+0.01
+10
+104
+107
+10-11
+0.1
+109
+1019
+1029
+1039
+�
+|T1
+1|/H4
+μ=0.01
+μ=0.1
+μ=1
+μ=10
+μ=100
+ξ=0
+ξ=
+1
+6
+FIG. 2. The absolute value of T 1
+1 component of the induced energy-momentum tensor is plotted in unit of H4 as a function of
+the electric field parameter λ = −eE/H2. The graphs correspond to different values of the mass parameter µ = m/H, and the
+coupling constant ξ as indicated. Both axes have logarithmic scales.
+behavior is assured. For fixed values of λ and ξ, the absolute values of the nonvanishing components are decreasing
+functions of µ. For fixed values of λ and µ, the nonvanishing components do not vary significantly with the parameter
+ξ in the range 0 ≤ ξ ≪ λ, µ. The qualitative behaviors shown in Figs. 1-3 can be given quantitative treatments by
+inspection of expressions (61)-(63) in the limiting regimes. We concentrate our attention on three regimes of interest:
+(1) The strong electric field regime with the criterion λ ≫ max(1, µ, ξ). (2) The heavy scalar field regime with the
+criterion µ ≫ max(1, λ, ξ). (3) The infrared regime with the criteria µ ≪ 1, λ ≪ 1, and ξ = 0.
+1.
+Strong electric field regime
+In the strong electric field regime λ ≫ max(1, µ, ξ), it is appropriate to find approximate behavior of the induced
+energy-momentum tensor in the limit λ → ∞. By expanding expressions (61)-(63) around λ = ∞ with µ and ξ fixed,
+we find the dominant terms in the components of the induced energy-momentum tensor
+T00 = −T11 = 3T22 = 3T33 = −Ω2 H4
+8π2
+� 7λ4
+240µ4
+�
+.
+(66)
+Thus, in this regime the absolute value of the nonvanishing components of induced energy-momentum tensor increase
+monotonically with increasing λ but decrease monotonically with increasing µ, as we see on the right end of any
+graphs in Figs. 1-3.
+2.
+Heavy scalar field regime
+In the heavy scalar field regime µ ≫ max(1, λ, ξ), it is appropriate to find approximate behavior of the induced
+energy-momentum tensor in the limit µ → ∞. By expanding expressions (61)-(63) around µ = ∞ with λ and ξ fixed,
+we find the dominant terms in the components of the induced energy-momentum tensor
+T00 = Ω2 H4
+8π2
+� a
+µ2 + b
+µ4 + c0λ2
+µ4
++ O(µ−6)
+�
+,
+T11 = −Ω2 H4
+8π2
+� a
+µ2 + b
+µ4 + c1λ2
+µ4
++ O(µ−6)
+�
+,
+T22 = T33 = −Ω2 H4
+8π2
+� a
+µ2 + b
+µ4 + c2λ2
+µ4
++ O(µ−6)
+�
+,
+(67)
+
+14
+0.01
+10
+104
+107
+10-9
+10
+1011
+1021
+1031
+1041
+λ
+|T2
+2|/H4
+μ=0.01
+μ=0.1
+μ=1
+μ=10
+μ=100
+ξ=0
+ξ=
+1
+6
+FIG. 3. The absolute value of T 2
+2 component of the induced energy-momentum tensor is plotted in unit of H4 as a function of
+the electric field parameter λ = −eE/H2. The graphs correspond to different values of the mass parameter µ = m/H, and the
+coupling constant ξ as indicated. Both axes have logarithmic scales. Recall that T 2
+2 = T 3
+3 .
+where the coefficients a, b, c0, c1 and c2 are given by
+a = − 2
+315 +
+¯ξ
+5 − 72¯ξ3,
+b = − 1
+210
+�
+1 − 32¯ξ + 504¯ξ2 − 90720¯ξ4�
+,
+c0 = − 1
+315 − 7¯ξ
+15 + 12¯ξ2,
+c1 = − 22
+315 + 3¯ξ
+5 + 12¯ξ2,
+c2 =
+2
+105 −
+¯ξ
+3.
+(68)
+The asymptotic forms in Eq. (67) reveal that the induced energy-momentum tensor falls off as H2/m2 in the limit
+(m/H) → ∞. Thus, the behavior of the induced energy-momentum tensor is inconsistent with the behavior of the
+semiclassical energy-momentum tensor [39, 62] that falls of as exp(−2πm/H) in the heavy scalar field regime where
+m ≫ H. A similar feature arises for the induced electric current of both scalar [61] and Dirac [73] fields in dS4.
+Studies [74, 75] have proposed explanations in physical terms for this feature of the induced electric current.
+3.
+Infrared regime
+To find approximate behavior of the induced energy-momentum tensor in the infrared regime, where µ ≪ 1, λ ≪ 1
+and ξ = 0, it is appropriate to make Taylor series expansions of the expressions (61)-(63) around µ = 0 and λ = 0,
+and set ξ = 0. We find that the dominant terms in the expansions of (61) and (63) are given by
+T00 = Ω2 H4
+8π2
+�61
+60 − 17λ2
+60µ2 −
+7λ4
+240µ4 + O
+�
+λ2, µ2��
+,
+(69)
+T22 = T33 = −Ω2 H4
+8π2
+�61
+60 + 11λ2
+180µ2 +
+7λ4
+720µ4 + O
+�
+λ2, µ2��
+,
+(70)
+which are valid for µ ≪ λ ≪ 1 as well as λ ≪ µ ≪ 1. The expansion of expression (62) for µ ≪ λ ≪ 1 takes the form
+T11 = Ω2 H4
+8π2
+�299
+60 + 7λ2
+36µ2 +
+7λ4
+240µ4 + O
+�
+λ2, µ2��
+,
+(71)
+while for λ ≪ µ ≪ 1 it is approximated by
+T11 = −Ω2 H4
+8π2
+�61
+60 − 223λ2
+36µ2 + 1433λ4
+240µ4 + O
+�
+λ2, µ2��
+.
+(72)
+
+15
+Observe that all the asymptotic expansions (69)-(71) diverge as m−4 in the exactly massless case, i.e., m = 0. We
+can understand the origin of these infrared-divergent terms by looking at the counterterms (57)-(59). These terms
+arise from the contribution of the zero modes in the massless case to the counterterms. And therefore signal that
+for the massless case the method of adiabatic regularization cannot be used because it leads to singularities in the
+counterterms, as pointed out in [19, 20, 61]. We emphasize that the result (72) is an approximation valid only for
+λ ≪ µ ≪ 1, and hence we cannot use it in the limit of zero mass for a fixed value of λ.
+B.
+Trace anomaly
+It will be reassuring to do a consistency check, to see that whether the induced energy momentum tensor yields the
+well-known predicted trace anomaly for a free, massless, conformally invariant scalar field in dS4. Putting the metric
+(2) and components (61)-(63) together, we obtain the trace of the induced energy-momentum tensor
+T = gµνTµν = H4
+8π2
+� 1
+15 −
+7λ4
+180µ4 −
+λ2
+45µ2 + 2¯ξλ2
+µ2
+− 72¯ξ2 + µ2
+3 − 12¯ξµ2 − λ2
+6 − 2λ2µ2
+3
+−
+3µ2γ
+2π2λ sin
+�
+2πγ
+�
+×
+�
+2πλ cosh
+�
+2πλ
+�
+− sinh
+�
+2πλ
+��
++
+iµ2
+2 sin
+�
+2πγ
+�
+� +1
+−1
+�
+3λ2r2 − λ2 − µ2 − 12¯ξ
+���
+e2πλr + e2iπγ�
+× ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr − µ2�
+µ2 + 12¯ξ
+�
+log
+�
+µ2�
++ iπµ2�
+µ2 + 12¯ξ
+��
+. (73)
+We see that the trace anomaly of the free, massless, conformally coupled complex scalar field is given by
+lim
+λ→0 lim
+µ→0 lim
+ξ→ 1
+6
+T =
+H4
+120π2 =
+2
+2880π2
+�1
+3R2 − RµνRµν�
+,
+(74)
+in arriving at the second equality, we have expressed H4 in terms of a combination of the Ricci tensor and the scalar
+curvature of dS4 which are given by Eq. (5), to put the result into a familiar form. The trace anomaly (74) is in
+agreement with the result of computing the trace anomaly [96] of a free, massless, conformally coupled real scalar
+field in dS4, except for the overall factor of 2 in Eq. (74) as explained below Eq. (65).
+V.
+IMPLICATIONS FOR THE INDUCED CURRENT
+The generalization of the nonconservation equation (23) for the classical energy-momentum tensor of the scalar field
+to the induced energy-momentum tensor Tµν, and the induced current jµ of the scalar field has important implications
+for the induced current. Recall that the nonvanishing components of Tµν are given by Eqs. (61)-(63), and the nonzero
+components of Fµν are given by Eq. (6). The only nontrivial relation that arises from Eq. (23) is obtained by setting
+ν = 0, which leads to
+∂0T 00 + HΩ
+�
+5T 00 + T 11 + T 22 + T 33�
+= −Ω−2Ej1,
+(75)
+where we have used Eqs. (4) and (6). The relation (75), along with the relations
+∂0T 00 = −2HΩ(τ)T 00,
+T = gµνT µν,
+−Ω−2Ej1 = HΩ−1A.j,
+(76)
+suffice to show that the timelike component of the induced energy-momentum tensor can be written in terms of the
+trace T , and the effective electromagnetic potential energy A.j as
+T00 = 1
+4Ω2�
+T + A.j
+�
+.
+(77)
+The induced current jµ is defined as the regularized expectation value of the scalar field electric current operator (14)
+in the in-vacuum state specified in Eq. (35). It can be verified that the induced current jµ is conserved and whose
+only non-vanishing component is j1. Thus, the induced current flows along the electric field background direction.
+For convenience we write the induced current as
+jµ = Ω(τ)J[n]δ1
+µ,
+(78)
+
+16
+here we use the subscript [n] to indicate the adiabatic order n of the subtracted counterterms to obtain the induced
+current J[n]. Comparison of Eqs. (61), (73), and (77) allows us to read off the effective electromagnetic potential
+energy A.j, and then we will use the last relation in Eq. (76) and definition (78) to extract J[4]. This gives
+J[4] = eH3
+8π2
+�4¯ξλ
+µ2 −
+λ
+9µ2 − 7λ3
+90µ4 + λ
+3 log
+�
+µ2�
+− iπλ
+3
+− 4λ3
+15 +
+γ
+6πλ
+�45
+π2 − 6 − 96¯ξ + 4λ2 − 8µ2�cosh
+�
+2πλ
+�
+sin
+�
+2πγ
+�
+−
+γ
+12π2λ2
+�45
+π2 − 6 − 96¯ξ + 64λ2 − 8µ2�sinh
+�
+2πλ
+�
+sin
+�
+2πγ
+� −
+iλ
+2 sin
+�
+2πγ
+�
+� +1
+−1
+�
+5λ2r4 −
+�
+1 + 36¯ξ + 6λ2 + 3µ2�
+r2
++ λ2 + µ2 + 12¯ξ
+���
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+�
+−
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+��
+dr
+�
+,
+(79)
+where the subscript [4] indicates J[4] has been derived from the expressions which have been regularized by the
+counterterms expanded up to fourth adiabatic order. This should be clear from Eqs. (61), (77), and (78). To verify
+our result (79), we have evaluated directly the induced current by calculating the expectation value of the current
+operator (14) in the in-vacuum state and then subtracting the corresponding counterterms expanded up to fourth
+adiabatic order. The expression for J[4] that follows from this direct analysis reproduces exactly the expression given
+by Eq. (79).
+In Ref. [61], the induced current of the massive, minimally coupled ξ = 0, scalar field has been evaluated by
+calculating the expectation value of the current operator (14) in the in-vacuum state which is represented by the mode
+functions given in Eqs. (30) and (31) with ξ = 0 for this case. In order to regularize the expectation value, the method
+of adiabatic subtraction was employed. Those authors expanded the required counterterm up to second adiabatic
+order that it suffices to remove the divergences and the regularized expression resulting from use of it reduces to the
+expected results in the Minkowski spacetime limit. We refer to this prescription as minimal subtraction. Furthermore,
+they argued that including the contribution of fourth adiabatic order in the counterterm spoils the expected behavior
+in the Minkowski spacetime limit. Following these restrictions and arguments, it was subsequently found in Ref. [61]
+that the induced current is given in terms of J[2] as in Eq. (78) by
+J[2] = eH3
+8π2
+�λ
+3 log
+�
+µ2�
+− iπλ
+3
+− 4λ3
+15 +
+¯γ
+6πλ
+�45
+π2 + 10 + 4λ2 − 8µ2�cosh
+�
+2πλ
+�
+sin
+�
+2π¯γ
+� −
+¯γ
+12π2λ2
+�45
+π2 + 10 + 64λ2 − 8µ2�
+× sinh
+�
+2πλ
+�
+sin
+�
+2π¯γ
+� −
+iλ
+2 sin
+�
+2π¯γ
+�
+� +1
+−1
+�
+5λ2r4 +
+�
+5 − 6λ2 − 3µ2�
+r2 + λ2 + µ2 − 2
+���
+e2πλr + e2iπ¯γ�
+× ψ
+�1
+2 + ¯γ + iλr
+�
+−
+�
+e2πλr + e−2iπ¯γ�
+ψ
+�1
+2 − ¯γ + iλr
+��
+dr
+�
+,
+(80)
+where ¯γ =
+�
+9/4 − λ2 − µ2 is obtained by setting ξ = 0 in the definition of γ, and the subscript [2] indicates J[2] has
+been regularized by the counterterms expanded up to second adiabatic order. It is important to note that there are
+two differences between expressions (79) and (80). First, the coupling constant ξ is treated as arbitrary real value
+parameter in the expression (79), whereas the expression (80) has been computed for fixed value ξ = 0. Second,
+expression (79) contains contributions from the fourth adiabatic order expansion of the counterterm. With these two
+differences, (79) is a generalization of (80). Therefore, the difference J[4]
+�
+ξ = 0
+�
+− J[2] would give only the fourth
+adiabatic order contribution of the counterterm to J[4], that is
+J[4]
+�
+ξ = 0
+�
+− J[2] = −eH3
+8π2
+� 7λ
+9µ2 + 7λ3
+90µ4
+�
+.
+(81)
+In our subsequent discussion, we demonstrate that the expected behavior of J[4] in Minkowski spacetime is not spoiled
+by these fourth adiabatic order contributions. Furthermore, we show that these contributions alter the behavior of
+the J[4] when compared to J[2], especially in the two regimes of the infrared hyperconductivity and the strong electric
+field.
+A.
+Minkowski spacetime limit
+Here we explore the behavior of the result (79) in the Minkowski spacetime limit. Note that in the limit where the
+Hubble constant tends to zero, i.e., H → 0 we recover Minkowski spacetime. As was mentioned in the discussion of
+Eq. (81), the difference between the expressions (79) and (80) comes from the contribution of fourth adiabatic order
+
+17
+0.001
+1
+1000
+10-6
+104
+1014
+1024
+λ
+μ=10-3
+μ=10-2
+μ=10-1
+μ=1
+μ=5
+μ=5
+J[4]
+J[2]
+FIG. 4. Dependence of the absolute values of the normalized induced currents |J[4]|/eH3 (solid curves) and |J[2]|/eH3 (dashed
+curves) on the electric field parameter λ = −eE/H2, for the case of minimal coupling ξ = 0. The graphs correspond to different
+values of the scalar field mass parameter µ = m/H as indicated. Both axes have logarithmic scales.
+in the adiabatic expansion of the counterterm. Comparison of the expressions (79) and (80) shows that these fourth
+adiabatic order contributions are
+δJ = eH3
+8π2
+�4¯ξλ
+µ2 −
+λ
+9µ2 − 7λ3
+90µ4
+�
+= − e
+8π2
+�eE
+m2
+��
+4¯ξH3 − H3
+9 − 7(eE)2
+90m2 H
+�
+.
+(82)
+where the second equality comes from using the definitions of λ and µ given in Eq. (27). It is clear from the second
+equality in Eq. (82) that all these terms vanish in the limit H → 0 for fixed and finite values of E and m. This
+observation will automatically insure the validity of (79) in the Minkowski spacetime limit.
+If the electric field
+background E and the scalar field mass m are regarded as fixed and finite, then by taking the limit H → 0 of the
+expressions (79), we find
+lim
+H→0 J[4] =
+e3
+12π3H E2e− πm2
+|eE| ,
+(83)
+which is exactly the same as the result obtained in Ref. [61] for the behavior of J[2], given by Eq. (80), in the
+Minkowski spacetime limit. It has been argued [61] that in the expanding dS the inverse of the Hubble constant
+H−1, in fact, is equivalent to the finite time interval between switching on and off the electric field background in
+Minkowski spacetime. By this argument, we can see that the behavior (83) of the induced current in the Minkowski
+spacetime limit agrees with the electric current of the charged scalar particles produced by the Schwinger mechanism
+in Minkowski spacetime [40, 41].
+A comparison of the result of this article for the induced current J[4] [see Eq. (79)] to the result of Ref. [61] for the
+induced current J[2] [see Eq. (80)] is shown in Fig. 4. The figure is drawn for ξ = 0, and illustrates that, for the light
+scalars µ < 1, the induced currents J[4] and J[2] differ considerably in the regime λ ≳ µ. Subsequently, we set ξ = 0
+and concentrate our attention on the regime λ ≳ µ. We examine the behaviors of J[4] and J[2] in the two regimes:
+The infrared hyperconductivity with the criterion µ < λ ≲ 1, and the strong electric field λ ≫ max(1, µ, ξ).
+B.
+Behaviors in the infrared hyperconductivity regime
+In Ref. [61], it was pointed out that, in the infrared hyperconductivity regime µ < λ ≲ 1, the absolute value of the
+induced current J[2] monotonically increases with decreasing the electric field parameter λ, as shown in Fig. 4. In this
+regime, we can approximate expression (80) by
+J[2] ≃ eH3
+8π2
+�
+6λ
+λ2 + µ2
+�
+.
+(84)
+
+18
+From Fig. 4 it is obvious that in the infrared hyperconductivity regime, the absolute value of the induced current J[4]
+reduces to zero at a certain value of the electric field parameter λ∗ which depends on the mass parameter µ. Indeed,
+the sign of J[4] changes at λ∗. This figure also indicates that the absolute value of J[4] is a decreasing function of λ
+in the interval µ < λ < λ∗ and is an increasing function for λ > λ∗. In the infrared hyperconductivity regime, we can
+approximate expression (79) by
+J[4] ≃ eH3
+8π2
+�
+− 7λ3
+90µ4 − 7λ
+9µ2 +
+6λ
+λ2 + µ2
+�
+.
+(85)
+This expression has a zero at λ∗ ≃ 2.090µ. In the range of λ > 2.090µ, the dominant contribution to J[4] comes from
+the first two terms in Eq. (85) which its absolute value increases with increasing λ. Thus, in this range, the infrared
+hyperconductivity phenomenon does not occur. On the other hand, in the interval µ < λ < 2.090µ, the dominant
+contribution to J[4] comes from the last term in Eq. (85) which increases with decreasing λ. Thus, in the interval
+µ < λ < 2.090µ, the infrared hyperconductivity phenomenon occurs. We therefore conclude that although there exist
+a period of the infrared hyperconductivity in our result for the induced current J[4], but now this phenomenon occurs
+in the more restricted interval µ < λ < 2.090µ.
+C.
+Behaviors in the strong electric field regime
+Figure 4 shows that although the absolute values of the two induced current J[2] and J[4] are increasing functions
+of λ in the strong electric field regime λ ≫ max(1, µ, ξ), the induced current J[2] does not depend on the scalar field
+mass, whereas the induced current J[4] is proportional to µ−4. We find that, in the limit λ → ∞ for a fixed µ, the
+induced current J[4] is given approximately by
+J[4] ≃ −eH3
+8π2
+� 7λ3
+90µ4
+�
+= 7He4
+720π2
+� E3
+m4
+�
+.
+(86)
+We observe that the behavior of the induced current J[4] in the Minkowski spacetime limit [see Eq. (83)] will be
+different from that in the strong electric field limit, see Eq. (86). Whereas, in [61] it was pointed out that the induced
+current J[2] has the same behavior in these two limits, indicated on the right side of Eq. (83). We note that in
+the Minkowski spacetime limit, the electric field strength E, the scalar field mass m, and the coupling constant ξ,
+are regarded as fixed and the Hubble constant H, tends to zero. Thus, in the Minkowski spacetime limit, although
+λ = −eE/H2 and µ = m/H tend to infinity, but the ratio λ/µ2 remains finite. We also note that in the strong electric
+field regime, the Hubble constant H, the scalar field mass m, and the coupling constant ξ, are regarded as fixed and
+the electric field strength E, tends to infinity. Thus, in this regime, λ goes to infinity while µ is regarded as a fixed
+and finite value.
+VI.
+CONCLUSIONS
+The aim of the present research was to examine the induced energy-momentum tensor of a massive, complex
+scalar field coupled to the electromagnetic vector potential (7) which describes a uniform electric field background
+with a constant energy density in the conformal Poincar´e patch of dS4 where the metric takes the form (2). The
+dynamics of the complex scalar field is governed by the action (11). The energy-momentum tensor of the scalar field
+is not covariantly conserved in the presence of the electromagnetic field, as the consequence of the electromagnetic
+interactions, see Eq. (23). The nonconservation of the scalar field energy-momentum tensor is compatible with the
+nonconservation of the electromagnetic field energy-momentum tensor [see Eq. (24)], and hence the total energy
+momentum tensor of the theory is covariantly conserved. We treated the classical gravitational field (2) and the
+classical electromagnetic field (7) as fixed field configurations which they are unaffected by the dynamics of the
+quantum complex scalar field in response to these backgrounds. We discussed canonical quantization of the scalar
+field. The normalized positive and negative frequency mode functions of the scalar field which behave like the positive
+and negative frequency Minkowski mode functions in the remote past are given by Eqs. (30) and (31). These mode
+functions determine the in-vacuum state of the scalar field.
+We calculated the expectation values of all the components of the energy-momentum tensor in the in-vacuum
+state of the scalar field; the nonzero expectation values have been obtained in Eqs. (40), (42), (44), and (46). It is
+expected that these expectation values contain ultraviolet divergences, because the expectation values in the Hadamard
+in-vacuum state suffer from the same ultraviolet divergence properties as Minkowski spacetime. To render these in-
+vacuum expectation values finite, we employed the adiabatic regularization method. To adjust the set of appropriate
+
+19
+counterterms, we treated the conformal scale factor and the electromagnetic vector potential as quantities of zero
+adiabatic order. As pointed out by Wald [18], in four dimensions, to obtain a renormalized energy-momentum tensor
+which is consistent with the Wald axioms, the subtraction counterterms should be expanded up to fourth adiabatic
+order. Under these assumptions, we then constructed the set of the appropriate adiabatic counterterms, which are
+given by Eqs. (57)-(60). The adiabatic regularization procedure was carried out by subtracting the counterterms
+from the corresponding unregularized in-vacuum expectation values. Thus we have arrived at our final expressions for
+all the nonvanishing components of the induced energy-momentum tensor, which are given by Eqs. (61)-(63). This
+research has shown that all the off-diagonal components of the induced energy-momentum tensor are zero, and the
+components T22 and T33 are equal as consequences of the underlying symmetries of the backgrounds (2) and (6).
+Furthermore, since the electric field background (6) is not invariant under full symmetries of dS, indeed violates the
+time reversal symmetry [51], and causes an electric current along its direction, we observe that T00, T11, and T22 are
+not equal to one another. The research has also shown that in the limit of zero electric field, our result for the induced
+energy momentum tensor reduces to the form (65). The expression (65) accords with the result of computing the
+renormalized vacuum energy-momentum tensor of a real scalar field in dS4 obtained in Refs. [11, 38], except for the
+overall factor of 2 in Eq. (65). This factor 2 is consistent with the complex scalar field as being made of two real
+scalar fields with the number of degrees of freedom doubling up. The absolute values of the expressions (61)-(63) as
+functions of the electric field parameter λ, for various values of the scalar field mass parameter µ, and two values of the
+coupling constant ξ are shown on the graphs in Figs. 1-3, respectively. These figures signal that the induced energy-
+momentum tensor is analytic and varies continuously with the parameters λ, µ, and ξ, this statement consistent with
+the requirements discussed in [95]. For fixed values of µ and ξ, the absolute values of the nonvanishing components
+of the induced energy-momentum tensor are increasing functions of λ, but by excluding a neighbourhood of the zero
+value points this behavior is assured. For fixed values of λ and ξ, the absolute values of the nonvanishing components
+are decreasing functions of µ.
+For a fixed λ and µ, the nonvanishing components do not vary significantly with
+the parameter ξ in the range 0 ≤ ξ ≪ λ, µ. The qualitative behaviors shown in Figs. 1-3 can be given quantitative
+treatments by inspection of expressions (61)-(63) in the limiting regimes. The examination of the expressions (61)-(63)
+has shown that in the strong electric field regime λ ≫ max(1, µ, ξ), the components of the induced energy-momentum
+tensor can be approximated by Eq. (66). In the heavy scalar field regime µ ≫ max(1, λ, ξ), the components can be
+approximated according to Eq. (67). We also found that in the infrared regime, where µ ≪ 1, λ ≪ 1, ξ = 0, the
+components can be approximated by Eqs. (69)-(72). To do a consistency check, we derived the trace anomaly of
+the induced energy-momentum tensor for the case of a free, massless, conformally invariant scalar field in dS4; see
+Eq. (74). This investigation shows that our result (74) is in agreement with the earlier result of computing the trace
+anomaly [96] of a free, massless, conformally coupled real scalar field in dS4, except for the overall factor of 2 in
+Eq. (74), as explained below Eq. (65).
+One of the more significant findings to emerge from this research is that the nonconservation equation (23) implies
+the relation (77) between the induced energy-momentum tensor and the induced current. This relation in turn implies
+the renormalization condition for the induced current. We derived the expression (79) for the induced current of the
+scalar field by using the expressions (61), (73), and relation (77). This result for the induced current has been derived
+from the expressions which have been regularized by the counterterms expanded up to fourth adiabatic order. In
+Ref. [61], the induced current of the massive, minimally coupled ξ = 0, scalar field has been evaluated by subtracting
+the counterterm expanded up to second adiabatic order; see Eq. (80). In the discussion of Eq. (83), we remarked that
+our result for the induced current in the Minkowski spacetime limit agrees with the electric current of the charged
+scalar particles produced by the Schwinger mechanism in Minkowski spacetime [40, 41]. A comparison of the result
+of this article for the induced current J[4] [see Eq. (79)] to the result of Ref. [61] for the induced current J[2] [see
+Eq. (80)] is shown in Fig. 4. The figure is drawn for ξ = 0, and illustrates that, for the light scalars µ < 1, the
+induced currents J[4] and J[2] differ considerably in the regime λ ≳ µ. From Fig. 4 it is obvious that in the infrared
+hyperconductivity regime µ < λ ≲ 1, the absolute value of the induced current J[4] reduces to zero at a certain
+value of the electric field parameter λ∗ which depends on the mass parameter µ. We found that in the infrared
+hyperconductivity regime, the induced current J[4] can be approximated by Eq. (85) which has a zero at λ∗ ≃ 2.090µ.
+In the interval µ < λ < 2.090µ, the dominant contribution to J[4] comes from the last term in Eq. (85) which increases
+with decreasing λ. Thus, the infrared hyperconductivity phenomenon occurs in the interval µ < λ < 2.090µ. We
+therefore conclude that although there exist a period of the infrared hyperconductivity in our result for the induced
+current J[4], but now this phenomenon occurs in the more restricted interval µ < λ < 2.090µ. Figure 4 also shows
+that the absolute value of the induced current J[4] is an increasing function of λ in the strong electric field regime
+λ ≫ max(1, µ, ξ), but decreases as µ−4 with increasing µ. We saw that in the limit λ → ∞ for a fixed µ, the induced
+current J[4] is given approximately by Eq. (86). The results of this investigation show that the behavior of the induced
+current J[4] in the Minkowski spacetime limit [see Eq. (83)] will be different from that in the strong electric field limit,
+see Eq. (86).
+This would be a fruitful area for further work. A natural progression of this work is to analyse the backreaction of
+
+20
+the induce energy-momentum tensor on the gravitational field of dS4 and the backreaction of the induce current J[4]
+on the electromagnetic field. This is also an issue for future research to explore the induced energy-momentum tensor
+of a Dirac field in the context of our discussion.
+ACKNOWLEDGMENTS
+E. B. very much appreciate the support by the University of Kashan Grant No. 1143880/1.
+Appendix: Evaluation of the momentum integrals over the mode functions
+In the appendix we present further supplementary data associated with the calculation of the expressions (36)-(38).
+It is convenient at this stage to switch to the three-dimensional spherical momentum space, and then we can perform
+the entire three-dimensional integrals in three-dimensional spherical coordinates. We introduce a transformation from
+the Cartesian momentum coordinates (kx, ky, kz) to the spherical momentum coordinates (k, θ, φ) by equations
+kx = k cosθ,
+ky = k sin θ cos φ,
+kz = k sin θ sin φ,
+(A.1)
+In this coordinates the variable r = kx/k is given by r = cos θ with range −1 ≤ r ≤ 1. The integration measure is then
+d3k = k2 sin θdφdθdk. It is useful to covert the variables of integration from the momentum k to the dimensionless
+physical momentum p = −kτ, and from the angle θ to the variable r. Thus, the previous expression for the integration
+measure may be rewritten as
+d3k = −H3Ω3(τ)dφdrp2dp.
+(A.2)
+Accordingly, we use a dimensionless physical momentum cutoff Λ, which is related to the momentum cutoff K as
+Λ = −Kτ. To begin the evaluation of (36)-(38), we change the integration measure according to (A.2) and substitute
+the expression (30) for Uk(x).
+After integration over azimuth angle φ and some simplifications, the expressions
+(36)-(38) reduce to
+�
+in
+��T00
+��in
+�
+= Ω2 H4
+8π2
+� +1
+−1
+dr
+�
+2I1 − 4λrI2 +
+�1
+4 − γ2 − 18¯ξ + λ2r2�
+I3 + 2ℑ
+�
+I4
+�
+− 2ℜ
+��
+6ξ − 1 − iλr
+�
+I5
+�
++ I6
+�
+,
+(A.3)
+�
+in
+��T11
+��in
+�
+= Ω2 H4
+8π2
+� +1
+−1
+dr
+�
+2r2I1 − 4λrI2 +
+��
+4ξ + 1
+�
+λ2 +
+�
+4ξ − 1
+�
+µ2 −
+�
+4ξ − 1
+�
+λ2r2
++
+�
+6ξ − 1
+��
+8ξ − 1
+��
+I3 − 2ℑ
+��
+4ξ − 1
+�
+I4
+�
++ 2ℜ
+��
+1 − 6ξ + iλr − 4iλrξ
+�
+I5
+�
+−
+�
+4ξ − 1
+�
+I6
+�
+,
+(A.4)
+and
+�
+in
+��T22
+��in
+�
+=
+�
+in
+��T33
+��in
+�
+= Ω2 H4
+8π2
+� +1
+−1
+dr
+��
+1 − r2�
+I1 +
+��
+4ξ − 1
+��
+λ2 + µ2 − λ2r2�
++
+�
+6ξ − 1
+��
+8ξ − 1
+��
+I3 − 2ℑ
+��
+4ξ − 1
+�
+I4
+�
++ 2ℜ
+��
+1 − 6ξ + iλr − 4iλrξ
+�
+I5
+�
+−
+�
+4ξ − 1
+�
+I6
+�
+,
+(A.5)
+where ℑ and ℜ stand for the imaginary and real parts of any expressions, respectively. In these expressions the
+momentum integrals over the Whittaker functions have been defined by
+I1 = eπλr
+� Λ
+0
+dpp3���Wκ,γ(−2ip)
+���
+2
+,
+(A.6)
+I2 = eπλr
+� Λ
+0
+dpp2���Wκ,γ(−2ip)
+���
+2
+,
+(A.7)
+
+21
+I3 = eπλr
+� Λ
+0
+dpp
+���Wκ,γ(−2ip)
+���
+2
+,
+(A.8)
+I4 =
+�1
+4 − γ2 − λ2r2 + iλr
+�
+eπλr
+� Λ
+0
+dpp2Wκ−1,γ(−2ip)W−κ,γ(2ip),
+(A.9)
+I5 =
+�1
+4 − γ2 − λ2r2 + iλr
+�
+eπλr
+� Λ
+0
+dppWκ−1,γ(−2ip)W−κ,γ(2ip),
+(A.10)
+I6 =
+���1
+4 − γ2 − λ2r2 + iλr
+���
+2
+eπλr
+� Λ
+0
+dppWκ−1,γ(−2ip)W−κ−1,γ(2ip).
+(A.11)
+The integrals in Eqs. (A.6)-(A.11) are of the same kind of those momentum integrals over the Whittaker functions
+which encountered in the calculation of the induced current of a scalar field in two- [60] and four-dimensional [61]
+de Sitter spacetimes. The first step in the evaluation of the integrals (A.6)-(A.11) by the method that explained in
+Ref. [61], is to plug the Mellin-Barnes representation (28) for the Whittaker function W and make use of the theorem
+of residues. It is rather straightforward, but rather lengthy, to show that our final results are
+I1 = Λ4
+4 + λr
+3 Λ3 + 1
+16
+�
+4γ2 + 12λ2r2 − 1
+�
+Λ2 + λr
+8
+�
+12γ2 + 20λ2r2 − 7
+�
+Λ +
+1
+128
+�
+27 + 48γ4 + 560λ4r4 − 120γ2
++ 480γ2λ2r2 − 520λ2r2�
+log
+�
+2Λ
+�
+− 7γ4
+32 + 83γ2
+64
+− 533
+96 λ4r4 + 1607
+192 λ2r2 − 59
+16γ2λ2r2 − 351
+512 −
+�55γ2
+24
++ 35λ2r2
+8
+− 355
+96
+�
+γλr
+sin
+�
+2πγ
+�
+�
+cos
+�
+2πγ
+�
++ e2πλr�
+−
+i
+256 sin
+�
+2πγ
+�
+�
+27 + 48γ4 + 560λ4r4 − 120γ2 + 480γ2λ2r2
+− 520λ2r2
+��
+π sin
+�
+2πγ
+�
++
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+�
+−
+�
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+��
+,
+(A.12)
+I2 = Λ3
+3 + λr
+2 Λ2 + 1
+8
+�
+4γ2 + 12λ2r2 − 1
+�
+Λ + λr
+8
+�
+12γ2 + 20λ2r2 − 7
+�
+log
+�
+2Λ
+�
+− 37
+12λ3r3 + 95
+48λr − 5γ2
+4 λr
+−
+�
+4γ2 + 15λ2r2 − 4
+�
+γ
+6 sin
+�
+2πγ
+�
+�
+cos
+�
+2πγ
+�
++ e2πλr�
+−
+iλr
+16 sin
+�
+2πγ
+�
+�
+12γ2 + 20λ2r2 − 7
+�
+×
+�
+π sin
+�
+2πγ
+�
++
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+�
+−
+�
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+��
+,
+(A.13)
+I3 = Λ2
+2 + λrΛ + 1
+8
+�
+4γ2 + 12λ2r2 − 1
+�
+log
+�
+2Λ
+�
+− γ2
+4 − 7λ2r2
+4
++ 5
+16 −
+3γλr
+2 sin
+�
+2πγ
+�
+�
+cos
+�
+2πγ
+�
++ e2πλr�
+−
+i
+16 sin
+�
+2πγ
+�
+�
+4γ2 + 12λ2r2 − 1
+��
+π sin
+�
+2πγ
+�
++
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+�
+−
+�
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+��
+,
+(A.14)
+I4 = − i
+16
+�
+4γ2 + 4λ2r2 − 4iλr − 1
+�
+Λ2 − 1
+8
+�
+4γ2 + 4λ2r2 − 4iλr − 1
+��
+1 + 2iλr
+�
+Λ − 3i
+128
+�
+4γ2 + 4λ2r2 − 4iλr
+− 1
+��
+4γ2 + 20λ2r2 − 20iλr − 9
+�
+log
+�
+2Λ
+�
++ 79
+32iλ4r4 + 47
+8 λ3r3 − 409
+64 iλ2r2 + 39γ2
+16 iλ2r2 − 109
+32 λr + 21γ2
+8
+λr
++ 7i
+32γ4 − 83i
+64 γ2 + 351i
+512 +
+γ
+4 sin
+�
+2πγ
+�
+�
+4γ2 + 15
+2 iλ3r3 + 15λ2r2 + 13
+2 iγ2λr − 97
+8 iλr − 4
+��
+cos
+�
+2πγ
+�
++ e2πλr�
+−
+3
+256 sin
+�
+2πγ
+�
+�
+4γ2 + 4λ2r2 − 4iλr − 1
+��
+4γ2 + 20λ2r2 − 20iλr − 9
+��
+π sin
+�
+2πγ
+�
++
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+�
+−
+�
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+��
+,
+(A.15)
+
+22
+I5 = − i
+8
+�
+4γ2 + 4λ2r2 − 4iλr − 1
+�
+Λ − 1
+8
+�
+4γ2 + 4λ2r2 − 4iλr − 1
+��
+1 + 2iλr
+�
+log
+�
+2Λ
+�
+− 2γ2 − 10λ2r2
+− 16
+3 iλ3r3 − 4iγ2λr + 20
+3 iλr + 3
+2 −
+iγ
+3 sin
+�
+2πγ
+�
+�
+8γ2 + 12λ2r2 − 18iλr − 8
+��
+cos
+�
+2πγ
+�
++ e2πλr�
++
+i
+16 sin
+�
+2πγ
+�
+�
+4γ2 + 4λ2r2 − 4iλr − 1
+��
+1 + 2iλr
+��
+π sin
+�
+2πγ
+�
++
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+�
+−
+�
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+��
+,
+(A.16)
+I6 = 1
+64
+�
+16γ4 − 8γ2 + 16λ4r4 + 32γ2λ2r2 + 8λ2r2 + 1
+�
+log
+�
+2Λ
+�
+− 3γ4
+16 + 7γ2
+32 − 25
+48λ4r4 − 7
+8γ2λ2r2 − 29
+96λ2r2
+− 11
+256 −
+γ
+48 sin
+�
+2πγ
+�
+�
+16γ4 − 8γ2 + 16λ4r4 + 32γ2λ2r2 + 8λ2r2 + 1
+��
+12λ3r3 + 20γ2λr + 7λr
+��
+cos
+�
+2πγ
+�
++ e2πλr�
+−
+i
+128 sin
+�
+2πγ
+�
+�
+16γ4 − 8γ2 + 16λ4r4 + 32γ2λ2r2 + 8λ2r2 + 1
+��
+π sin
+�
+2πγ
+�
++
+�
+e2πλr + e−2iπγ�
+ψ
+�1
+2 − γ + iλr
+�
+−
+�
+e2πλr + e2iπγ�
+ψ
+�1
+2 + γ + iλr
+��
+,
+(A.17)
+where we use log(z) to denote the natural logarithm function, and ψ(z) to denote the digamma function. By substi-
+tuting Eqs. (A.12)-(A.17) into expressions (A.3)-(A.5) and performing the integrals over r, we obtain the results (40),
+(42), and (44), respectively.
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diff --git a/DNE2T4oBgHgl3EQf9Qm6/content/tmp_files/load_file.txt b/DNE2T4oBgHgl3EQf9Qm6/content/tmp_files/load_file.txt
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@@ -0,0 +1,1989 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf,len=1988
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='04227v1  [hep-th]  10 Jan 2023  Induced energy-momentum tensor in de Sitter scalar QED and its implication for  induced current  Omid Gholizadeh Meimanat and Ehsan Bavarsad∗  Department of Physics, University of Kashan, 8731753153 Kashan, Iran  The aim of this research is to investigate the vacuum energy-momentum tensor of a quantized,  massive, nonminimally coupled scalar field induced by a uniform electric field background in a four-  dimensional de Sitter spacetime (dS4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We compute the expectation value of the energy-momentum  tensor in the in-vacuum state and then regularize it using the adiabatic subtraction procedure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  The correct trace anomaly of the induced energy-momentum tensor that confirmed our results is  significant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The nonconservation equation for the induced energy-momentum tensor imposes the  renormalization condition for the induced electric current of the scalar field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The findings of this  research indicate that there are significant differences between the two induced currents which are  regularized by this renormalization condition and the minimal subtraction condition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  INTRODUCTION  In the past several decades quantum field theory in curved spacetime has played a major role in the study of  the effects of gravity on quantum fields;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' for an pedagogical introduction see [1–3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A precise understanding of the  quantum effects in curved spacetime was acquired by the late 1960s by Parker [4–6] and followed by investigations of  others.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Indeed, these early investigations focused primarily on the physical consequences of particle creation in the  cosmological spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It has been illustrated that a time-varying gravitational field creates elementary particles  from the vacuum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker discovered that this particle creation process can be analyzed by using the Bogoliubov  transformations method [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Formulating a general framework of quantum field theory in curved spacetime involves  nontrivial questions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  The problem of particle concept is a deep one, and it is associated with one of the most  fundamental difficulties of quantum field theory in curved spacetime, that there is no an unambiguous or unique  vacuum state;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' a detailed discussion can be found in [1, 2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This ambiguity is reflected in the theory by the absence of  an unambiguous or unique preferred mode solutions of the field equation, which is in turn a consequence of symmetry  group of the spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Since in a general nonstatic curved spacetime there is generically no any timelike Killing  vector field, it is not possible to classify modes as positive-frequency or negative-frequency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Indeed, it is possible to  construct a compleat set of modes, however the problem is that there are many of such sets and we will not have  any criterion available to select a unique privileged choice of the modes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' One of the key lessens learned from the  development of this subject is that the notion of particle number does not generally have universal significant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Hence,  the expectation value of the energy-momentum tensor in a suitable vacuum state is perhaps more physically relevant  object to probe the structure of quantum fields in curved spacetime rather than particle number quantity [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Part of  reason is that the expectation value of the energy-momentum tensor in a fixed vacuum state transforms according to  the usual tensor transformation law.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In particular, if the vacuum expectation value of the energy-momentum tensor  vanishes for an observer, it will vanish for all observers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' On the contrary, the expectation of particle number is an  essential observer-dependent quantity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The energy-momentum tensor is also important, because it is directly relevant  to explore the consequences of the quantum field dynamics for the geometry of the spacetime through the Einstein  equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Hence, it is interesting to investigate the expectation value of the energy-momentum tensor in a suitable  vacuum state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Since the mid-seventies, significant advances have been made in the computation of the energy-momentum tensor of  the quantum fields as well as its applications in the cosmological context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' An essential feature of these computations  is that they all involve the ultraviolet divergencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  In fact, such divergencies occur naturally in quantum field  theory calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Various prescriptions have been developed for rendering the energy-momentum tensor finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Among these prescriptions, Pauli-Villars regularization [7, 8], dimensional regularization [9–11], and zeta-function  regularization [11–14] were originally developed for use in Minkowski spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Several sets of fictitious fields may  be necessary to remove all of the divergences, making Pauli-Villars regularization rather complicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In [13], it was  pointed out that dimensional regularization procedure is ambiguous in curved spacetime due to the fact that in some  classes of spacetimes, there is no natural way to generalize the dimensionality of the spacetime and the answer would  be different in different extensions to D dimensions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This method also suffers from limitation that one needs, in  ∗ bavarsad@kashanu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ir  2  principle, to solve the field equations exactly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Another often used regularization procedure is point-splitting technique  [15–18] which is intrinsically designed to be used in the position-space representation of the composite operators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  This regularization is implemented by placing the two quantum fields at distant points separated by an infinitesimal  distance in a nonnull direction and then the divergencies that arise in the coincidence limit are absorbed into the  renormalized parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Although point-splitting technique is the most applicable regularization scheme, it involves  considerable technical complication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' An alternative regularization prescription is adiabatic subtraction [19–23] which  was originally invented by Parker [5] to obtain the average density of the scalar particles created in a spatially flat  Friedmann-Lemaitre-Robertson-Walker (FLRW) universe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This approach is only applicable in spacetimes with slowly  varying curvature, and in fact an adiabatic expansion is an expansion in number derivatives of the spacetime metric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Hence, it is especially useful for studies that involve numerical techniques and problems of cosmological interest  [22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In order to arrive a sensible semiclassical backreaction theory of quantum fields in curved spacetime, Wald has  propounded [24] a minimal set of properties that the renormalized energy-momentum tensor should satisfy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' These  properties which are often called the Wald axioms, in the weaker set of axioms, can be expressed as follows [1, 3]:  (1) The expectation value of the energy-momentum tensor in any state at a point p in spacetime is covariant under  general coordinate transformations (diffeomorphisms) and is independent of spacetime geometry at any point q ̸= p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (2) The off-diagonal matrix element of energy-momentum tensor between any orthogonal pairs of states is finite and  unambiguous.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (3) For all states, the expectation value of the energy-momentum tensor is covariantly conserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (4) The expectation value of the energy-momentum tensor vanishes in the relevant vacuum state in the Minkowski  spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It was shown in [18] that the fifth axiom of Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [24] cannot be satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Wald then proved a remarkable  result, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', the uniqueness theorem, which states that if the expectation value of the energy-momentum tensor satisfies  the Wald axioms (1)-(3), then it is unique up to the addition of a local conserved tensor [24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Hence, the final results  for the renormalized energy-momentum tensor do not depend on the employed regularization method [1, 3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Using  these regularization techniques, the regularized and renormalized energy-momentum tensor of a neutral scalar field  has been widely investigated in FLRW universes [19–22, 25–33] and its physical implications for cosmological issues  have been explored [34–36].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  It is thought that the very early universe can be approximately described by de Sitter spacetime (dS) [2], which  motivates us to study the quantum field theory in this spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Gibbons and Hawking [37] originally discovered  that an inertial observer with a particle detector at rest perceives the de Sitter invariant vacuum state as a bath of  thermal radiation which apparently comes from the cosmological event horizon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In this context, a relatively simple  model problem is that of a neutral scalar field with no self-interactions whose regularized and renormalized energy-  momentum tensor has been analyzed [11, 38–45].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In [39–41], it was subsequently shown that the vacuum state of the  quantum field in dS is unstable to particle creation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Furthermore, the study of semiclassical backreaction effect of  the quantum corrections onto the Hubble rate in [42] indicated that these contributions can potentially result in a  superacceleration phase, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', a phase when the Hubble rate increases as the dS expands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The spontaneous creation  of pairs of charged particles from the vacuum by a strong electric field background in Minkowski spacetime is a  well-known nonperturbative feature of quantum field theory [46–48].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Since the clearest version of this effect was  worked out by Schwinger, it is named the Schwinger effect;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' reviews of this subject can be found in, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', [49, 50].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The  phenomenon of particle creation has revealed the close analogy between quantum field theory in dS and a constant,  uniform electric field in Minkowski spacetime [40, 41, 51, 52].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This analogy motivates us to explore the combined  implications of the dS Gibbons-Hawking effect and the Schwinger effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Aside from this analogy, there are arguments  and evidences that require the existence of strong electromagnetic fields in the early universe [53, 54].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This logical  possibility provides a further reason for studying quantum field theory in the presence of an electric field in dS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  There has been numerous studies to investigate the Schwinger pair creation by a uniform electric field background  with the constant energy density in a dS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Seminal contributions have been made by [55, 56].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  The Bogoliubov  transformation method has been used to analyze the Schwinger effect for the charged scalar field in two- [55–60],  four- [61], and arbitrary-dimensional [62] de Sitter spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The Bogoliubov transformation method has been  used to investigate the Schwinger effect for the Dirac field in dS [63–67], in a manner similar to that used for the  corresponding charged scalar field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In this method of analysis, which bring its own insights, the expectation value for  the number of particles is related to the Bogoliubov coefficients which, in turn, can be determined by specifying the  in-vacuum and out-vacuum states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A reasonable definition of the out-vacuum state requires that the parameters mass  of the quantum field and the electric field strength to satisfy the semiclassical condition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For a created semiclassical  particle, this condition implies that either or both the mass and the magnitude of its electric potential energy acroses  one Hubble radius must be much greater than the energy scale determined by the spacetime curvature [60, 61].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' An  immediate consequence of the semiclassical condition is that the entire physical ranges of the parameters mass and  electric field strength cannot be probed by this method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A useful alternative approach for studying the Schwinger  effect in dS was introduced in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [60].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In this approach the expectation values of the objects such as the electric  current and the energy-momentum tensor of the quantum field in the in-vacuum state are investigated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The choose  of the in-state as the vacuum is justified form various viewpoints;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' see [55].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Regarding the regularity properties, it is a  3  Hadamard and adiabatic state [56, 60].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The regularized expectation value of the electric current (also called induced  current) in the in-vacuum state of the charged scalar field coupled to a constant, uniform electric field background  has been evaluated in two- [60], three- [62], and four-dimensional [61, 68] de Sitter spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In those analyses the  behavior of the induced current can be probed in the infrared regime for which the quantum field mass is smaller than  the magnitude of the electric potential energy acroses one Hubble radius which in turn is smaller than the energy scale  determined by the spacetime curvature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The authors found that, although the induced current has been computed  using different regularization method, in the infrared regime the induced current increases with deceasing electric field  strength [60–62, 68].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This peculiar behavior was first observed in [60] and is called the infrared hyperconductivity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In  [69], the authors gave an alternative derivation of the infrared hyperconductivity phenomenon in dS4 using the uniform  asymptotic approximation method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For a charged scalar field coupled to a uniform electromagnetic field background  with a constant energy density electric field parallel to a conserved flux magnetic field in dS4, the Schwinger effect  using Bogoliubov transformation method [70–72] and the induced current [70, 71] in the in-vacuum state have been  investigated;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' and a period of infrared hyperconductivity was found.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The in-vacuum induced current of the Dirac field  coupled to a constant, uniform electric field background in two- [65] and four-dimensional [73] de Sitter spacetimes  has been analyzed in a manner similar to that used for the corresponding scalar field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It was subsequently found that,  in contrast to the case of corresponding scalar field, the infrared hyperconductivity phenomenon does not occur in the  induced current of the Dirac field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Another peculiar behavior of the induced current occurs when the direction of the  induced current is opposite the direction of applied electric field background.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This phenomenon which is called the  negative current, has been reported for both the scalar field [61, 68] with essentially small mass and the Dirac field  [73] with any mass in the four-dimensional de Sitter spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For the scalar field case the negative current occurs in  a finite interval of the electric field strength, and for the Dirac field case it occurs below a certain value of the electric  field strength which depends on the mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [74, 75], some notable attempts have been made to explain and  remedy these peculiarities of the induced current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Beside the induced current, the regularized expectation value of the  energy-momentum tensor (also called the induced energy-momentum tensor) in the in-vacuum state of the charged  scalar [76–78] and Dirac [79] quantum fields coupled to a constant, uniform electric field background has been analyzed  in different dimensions of dS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In two-dimensional dS, the induced energy-momentum tensor of the charged scalar field  has been analyzed in [76], and subsequently the nonperturbative, regularized, one-loop effective Lagrangian of scalar  QED has been constructed;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' the induced energy-momentum tensor of the corresponding Dirac field has been derived  in [79], and then applied to study of the gravitational backreaction effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The trace of the induced energy-momentum  tensor of the charged, massive scalar field conformally coupled to the Ricci scalar curvature of three- [77] and four-  dimensional [78] de Sitter spacetimes has been computed;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' and to examine the evolution of the Hubble constant, the  induced energy-momentum tensor has been obtained from the trace, along with the assumption that the created pairs  act like a perfect fluid with a vacuum equation of state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By applying the Bogoliubov transformation method, the  energy-momentum tensor of the Schwinger scalar pairs created by a constant, uniform electric field background in an  arbitrary dimensional dS has been computed under the two limiting conditions, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', the heavy scalar field [62] and  the strong electric field [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In both these cases, it was found that the Hubble constant decays as a consequence  of the Schwinger pair creation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Before closing the present section, it is worthwhile to mention that the Schwinger  effect has been studied in FLRW spacetimes [81] and in the framework of cosmological models [69, 82–92].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The role  of strong electromagnetic fields in astrophysics and cosmology was reviewed in [93].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The objectives of this article  are to investigate the induced energy-momentum tensor of the charged scalar field coupled to a uniform electric field  background in dS4, and to analyze its nonconservation equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The importance and originality of this study are that  it calculates the induced energy-momentum tensor and explores a relation between the induced energy-momentum  tensor and the induced current which leads to new insights into the regularization and behavior of the induced current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  The remaining part of the article proceeds as follows: In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' II, we define and construct the basic elements of  the formalism that will be necessary in our subsequent discussions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We then carry out explicit computation of the  induced energy-momentum tensor in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The properties of the induced energy-momentum tensor are explored  in detail in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' V, we analyze the nonconservation equation of the induced energy-momentum tensor,  this investigation yields a relation between the induced energy-momentum tensor and the induced current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Then the  properties of the resulting induced current are discussed in detail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' VI, we present the findings of the research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  In the Appendix we present further supplementary data associated with the calculation of the expectation values of  the components of the energy-momentum tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  BASIC DEFINITIONS AND CONSTRUCTIONS  In this section we shall define and construct the basic elements of the formalism that will be necessary in our  subsequent discussions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  4  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Specification of the model  We have already mentioned that we consider a massive complex scalar field ϕ(x), coupled to the electromagnetic  vector potential Aµ(x), which describes a uniform electric field background with a constant energy density in the  conformal Poincar´e patch of dS4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To represent this region of dS4 which is conformally related to a region of Minkowski  spacetime, we choose the coordinates xµ = (τ, x) that the ranges of the conformal time τ, and the comoving spatial  coordinates x are given by  τ ∈  �  − ∞, 0  �  ,  x ∈ R3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (1)  In terms of these coordinates the metric of the spacetime takes the form  gµνdxµdxν = Ω2(τ)  �  dτ 2 − dx · dx  �  ,  (2)  with the conformal scale factor  Ω(τ) = − 1  Hτ ,  (3)  where H is the Hubble constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The nonzero Christoffel symbols for the metric (2) are given by  Γ0  00 =  ˙Ω  Ω,  Γ0  ij =  ˙Ω  Ωδij,  Γi  0j =  ˙Ω  Ωδi  j,  (4)  where the roman indices i, j denote only three spatial components and run from 1 to 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We use the overdot to denote  differentiation with respect to the conformal time τ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' From Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (4) the Ricci tensor and hence the Ricci scalar can be  calculated  Rµν = 3H2gµν,  R = 12H2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (5)  We put a uniform electric field background with a constant energy density on the Poincar´e patch represented in  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Without loss of generality, we choose our coordinates so that this electric field to point in the x1 direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Thus the nonzero components of the electromagnetic field tensor are  F01 = −F10 = Ω2(τ)E,  (6)  where E is a constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is convenient to express this electromagnetic field tensor in terms of a vector potential in  the Coulomb gauge [60–62] as  Aµ(τ) = − E  H2τ δ1  µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (7)  The compleat action Stot of this theory can be represented as sum of a pure gravitational piece, an electromagnetic  piece, and a scalar field piece  Stot = Sgr + Sem + S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (8)  Here Sgr is the Einstein-Hilbert action that only includes the gravitation piece of the compleat action, and is given by  Sgr =  1  16πG  �  d4x√−g  �  R − 2Λc  �  ,  (9)  where G is Newton’s gravitational constant, g is the determinant of the metric, R is the Ricci scalar of the spacetime,  and Λc is the cosmological constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The electromagnetic piece of the compleat action is expressed in terms of the  electromagnetic field tensor as  Sem = −1  4  �  d4x√−gFµνF µν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (10)  The dynamics of the complex scalar field ϕ(x) of mass m coupled to the electromagnetic vector potential (7) with  coupling e is governed by the last piece of the compleat action which can be written as  S =  �  d4x√−g  �  gµν�  ∂µ + ieAµ  �  ϕ  �  ∂ν − ieAν  �  ϕ∗ − (m2 + ξR)ϕϕ∗�  ,  (11)  5  where ξ is a dimensionless nonminimal coupling constant which describes the strength of the coupling ϕ to the Ricci  scalar (5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The Euler-Lagrange equations of motion give the Klein-Gordon equation for the scalar field  1  √−g ∂µ  �√−ggµν∂νϕ  �  + 2iegµνAµ∂νϕ − e2gµνAµAνϕ + (m2 + ξR)ϕ = 0,  (12)  and the Maxwell equation for the electromagnetic field  ∇νF νµ = jµ,  (13)  where ∇ denotes the covariant derivative operator, and jµ is the electric current of the scalar field caused by the  electric field background (6) which is defined by  jµ(x) = iegµν��  ∂νϕ + ieAνϕ  �  ϕ∗ − ϕ  �  ∂νϕ∗ − ieAνϕ∗��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (14)  It is straightforward to verify that ∇µjµ = 0, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', the electric current is conserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Preliminary definition of the energy-momentum tensor  The classical Einstein equation can be derived from the compleat action (8) by demanding the invariance of Stot  under infinitesimal variation of the metric δgµν, or equivalently, infinitesimal variation of the inverse metric δgµν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  This condition requires that  2  √−g  δStot  δgµν =  2  √−g  � δSgr  δgµν + δSem  δgµν + δS  δgµν  �  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (15)  The Variation of expression (9) with respect to δgµν leads to  2  √−g  δSgr  δgµν =  1  8πG  �  Rµν − 1  2Rgµν + Λcgµν  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (16)  The variations of the electromagnetic action Sem, and the scalar field action S, with respect to δgµν define the  energy-momentum tensor of the electromagnetic field T (em)  µν  , and the energy-momentum tensor of the scalar field Tµν,  respectively, as  2  √−g  δSem  δgµν = T (em)  µν  ,  (17)  2  √−g  δS  δgµν = Tµν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (18)  Plugging expressions (10) and (11) into Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (17) and (18),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' respectively,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' and following the standard calculus of  variations procedure yields the energy-momentum tensor of the electromagnetic field  T (em)  µν  = 1  4gµνFρσF ρσ + gρσFµρFσν,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (19)  and a preliminary expression for the energy-momentum tensor of the scalar field  Tµν =  ��  4ξ − 1  �  gρσ�  ∂ρ + ieAρ  �  ϕ  �  ∂σ − ieAσ  �  ϕ∗ +  �  1 − 4ξ  �  m2ϕϕ∗ +  �1  2 − 4ξ  �  ξRϕϕ∗�  gµν  +  �  1 − 2ξ  ��  ∂µϕ∂νϕ∗ + ∂νϕ∂µϕ∗�  + ieAµ  �  ϕ∂νϕ∗ − ∂νϕϕ∗�  + ieAν  �  ϕ∂µϕ∗ − ∂µϕϕ∗�  + 2e2AµAνϕϕ∗ + 2ξΓρ  µν  �  ϕ∂ρϕ∗ + ∂ρϕϕ∗�  − 2ξ  �  ∂µ∂νϕϕ∗ + ϕ∂µ∂νϕ∗�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (20)  Plugging three expressions (16)-(18) into Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (15) gives the Einstein equation  Rµν − 1  2Rgµν + Λcgµν = −8πG  �  T (em)  µν  + Tµν  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (21)  6  An important property of the Einstein equation is that both sides of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (21) have identically vanishing covariant  divergences, which implies  ∇µT µν = −∇µT (em)µν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (22)  Using the Klein-Gordon Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (12), it is straightforward to show that the covariant divergence of expression (20) is  given by  ∇µT µν = −jµF µν,  (23)  Apparently, the energy-momentum tensor of the scalar field is not covariantly conserved in the presence of the  electromagnetic field, as the consequence of the electromagnetic interactions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We show that the nonconservation of  Tµν is compatible with the nonconservation of T (em)  µν  so that the relation (22) is satisfied, and hence the total energy  momentum tensor is covariantly conserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By taking the covariant divergence of the expression (19) and using the  Maxwell equation (13), it is seen that  ∇µT (em)µν = jµF µν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (24)  As a result of Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (23) and (24), it is evident that the relation (22) is satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Hence, the total energy-momentum  tensor Tµν + T (em)  µν  is manifestly conserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  It will be important to state that we will treat the classical gravitational field (2) and the classical electromagnetic  field (7) as fixed field configurations which they are unaffected by the dynamics of the quantum complex scalar field  ϕ(x) in response to these backgrounds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In fact, the Einstein equation (21) describes the backreaction effects on the  gravitational field, and the Maxwell equation (13) and Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (24) describe the backreaction effects on the electromagnetic  field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Indeed, due to the conceptual importance of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (23) in our subsequent discussions, we have presented Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (13),  (21), and (24) to provide a fairly detailed discussion of its derivation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is then clear that we do not discuss these  equations further in this article.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Quantizing the complex scalar field  Quantizing the complex scalar field ϕ(x), in the classical gravitational (2) and electromagnetic (7) field backgrounds  is completely straightforward and follows exactly the same route as that of a complex scalar field in Minkowski  spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We will solve the Kline-Gordon Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (12), and then adopting canonical quantization method, we can define  the in-vacuum state to obtain the expectation value of the energy-momentum tensor operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Taking account of the fact that the gravitational (2) and electromagnetic (7) backgrounds are invariant under  spatial translations, it is convenient to write the mode solution of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (12) as  Uk(x) = Ω−1(τ)eik·xf(τ),  (25)  where k is the comoving momentum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Plugging Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (2), (7), and (25) into Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (12), we can put the differential  equation in a standard form by the change of variable z = 2ikτ so that k = |k|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Then it becomes  d2f  dz2 +  �  − 1  4 + κ  z + 1/4 − γ2  z2  �  f(z) = 0,  (26)  where the dimensionless parameters are defined through  µ = m  H ,  λ = − eE  H2 ,  ¯ξ = ξ − 1  6,  r = kx  k ,  κ = −iλr,  γ =  �  1  4 − λ2 − µ2 − 12¯ξ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (27)  Two values of ξ are of particular interest that are the minimally coupled case ξ = 0, and conformally coupled  case ξ = 1/6 which implies ¯ξ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The variable kx which appears in the definition of the parameter r, denotes  the component of the comoving momentum k along the electric field background.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Equation (26) is the Whittaker  equation, and the solutions are called Whittaker functions;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' see, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', [94].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We define the in-vacuum state |in⟩ so  that in the remote past (τ → −∞) where the spacetime is asymptotically Minkowskian, an inertial observer there  would identify this state with a physical vacuum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This vacuum state may be represented by a mode solution of the  Whittaker Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (26) which behaves like a mode function in Minkowski spacetime in the limit of τ → −∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Hence, the  7  solution of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (26) with the desired asymptotic form in the limit of |z| → ∞ which can be represented in terms of a  Mellin-Barnes integral [94] is  Wκ,γ(z) =  e− z  2  Γ  � 1  2 + γ − κ  �  Γ  � 1  2 − γ − κ  �  � +i∞  −i∞  ds  2πiΓ  �1  2 + γ + s  �  Γ  �1  2 − γ + s  �  Γ  �  − κ − s  �  z−s,  (28)  with the condition that the phase of the variable z and the values of the parameters γ and κ must satisfy the following  inequalities  ��ph(z)  �� < 3π  2 ,  1  2 ± γ − κ ̸= 0, −1, −2, · · · .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (29)  In expression (28), the factors denoted by Γ are the gamma functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The contour of the Mellin-Barnes integral (28)  consists of a straight vertical line from minus infinity to infinity, parallel to imaginary axis in the complex plane, and  of a semicircle at infinity with indentations if necessary to avoid poles of the integrand in a way that separates the  poles of Γ  � 1  2 + γ + s  �  and Γ  � 1  2 − γ + s  �  from the poles of Γ  �  − κ − s  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The normalized mode functions which behave  like the positive frequency Minkowski mode functions in the remote past are given by [61, 62],  Uk(x) =  1  √  2k  e  iπκ  2 Ω−1(τ)eik·xWκ,γ  �  2ikτ  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (30)  Besides, the normalized mode functions which behave like the negative frequency Minkowski mode functions in the  remote past are found to be [61, 62],  Vk(x) =  1  √  2k  e− iπκ  2 Ω−1(τ)e−ik·xWκ,γ  �  − 2ikτ  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (31)  We have conventionally normalized the mode functions (30) and (31) such that their Wronskian to be  Uk ˙U ∗  k − U ∗  k ˙Uk = V ∗  k ˙Vk − Vk ˙V ∗  k = iΩ−2(τ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (32)  These mode functions will be orthonormal with respect to the conserved scalar product integrated over the constant  τ hypersurface [62].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The usual canonical quantization will proceed by introducing the creation a†  k, and annihilation  ak operators for each of mode functions Uk, and similarly the creation b†  k, and annihilation bk operators for each of  mode functions Vk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The creation and annihilation operators satisfy the commutation rules  �  ak, a†  k′  �  =  �  bk, b†  k′  �  = (2π)3δ  �  k − k′�  ,  (33)  with all other commutators vanishing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Then, the complex scalar field operator can be expanded in terms of the  creation and annihilation operators in the standard manner as  ϕ(x) =  �  d3k  (2π)3  �  akUk(x) + b†  kVk(x)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (34)  The in-vacuum state |in⟩ is characterized by the fact that it is annihilated by each of ak and bk operators  ak  ��in  �  = bk  ��in  �  = 0,  ∀k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (35)  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  CONSTRUCTION OF THE INDUCED ENERGY-MOMENTUM TENSOR  Having built a foundation for our discussion and presented the definition for the energy-momentum tensor of the  scalar field in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (20), we will proceed to present the regularized in-vacuum expectation value of the energy-momentum  tensor of the scalar field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Unregularized expectation values in the in-vacuum state  Integral representations for the in-vacuum expectation values of the components of the energy-momentum tensor  can be obtained by substituting the mode expansion (34) for the quantum scalar field ϕ(x) into the definition (20),  8  and then calculating the expectation values in the in-vacuum state using relations (33) and (35).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By using Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (12)  and some algebra, we have the following integral expressions in terms of the positive frequency mode function (30)  for the expectation values of the components.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The integral expression of the timelike component is given by  �  in  ��T00  ��in  �  =  �  d3k  (2π)3  �  ˙Uk ˙U ∗  k − 6ξτ −1�  Uk ˙U ∗  k + ˙UkU ∗  k  �  + τ −2�  k2τ 2 + 2λrkτ + λ2 + µ2 + 6ξ  �  UkU ∗  k  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (36)  For the diagonal spacelike components we get  �  in  ��T11  ��in  �  =  �  d3k  (2π)3  ��  1 − 4ξ  � ˙Uk ˙U ∗  k − 2ξτ −1�  Uk ˙U ∗  k + ˙UkU ∗  k  �  + τ −2��  4ξ − 1 + 2r2�  k2τ 2 + 2  �  4ξ + 1  �  λrkτ  +  �  4ξ + 1  �  λ2 +  �  4ξ − 1  �  µ2 + 6ξ  �  8ξ − 1  ��  UkU ∗  k  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (37)  and  �  in  ��T22  ��in  �  =  �  in  ��T33  ��in  �  =  �  d3k  (2π)3  ��  1 − 4ξ  � ˙Uk ˙U ∗  k − 2ξτ −1�  Uk ˙U ∗  k + ˙UkU ∗  k  �  + τ−2��  4ξ − 1  �  k2τ 2  + 2k2  zτ 2 + 2  �  4ξ − 1  �  λrkτ +  �  4ξ − 1  �  λ2 +  �  4ξ − 1  �  µ2 + 6ξ  �  8ξ − 1  ��  UkU ∗  k  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (38)  The only nonvanishing in-vacuum expectation values of the off-diagonal components can be expressed as  �  in  ��T01  ��in  �  =  �  in  ��T10  ��in  �  = iτ −1  �  d3k  (2π)3  �  rkτ + λ  ��  Uk ˙U ∗  k − ˙UkU ∗  k  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (39)  Using the asymptotic expansion of the Whittaker function (28) for large values of its argument [94], it can be shown  that the mode function (30) is proportional to k− 1  2 −iλr in the limit of k → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Then, inspection of integrals in  Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (36)-(39) shows that these expressions are ultraviolet divergent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, we first regulate them by cutting them  of at a large momentum K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Further description of the calculation of the expressions (36)-(38) is available in the  Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We find the final expression for the unregularized in-vacuum expectation value of the timelike component  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T00  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='= Ω2(τ) H4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ4 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='µ2 − 6¯ξ + 2λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ2 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + 6¯ξµ2 − λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2Λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ 54¯ξ2 − 2λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='15 + µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4 + 6¯ξµ2 + µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 19λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='72  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 2λ2¯ξ − λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24π  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2 − 6 − 96¯ξ + 4λ2 − 26µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�cosh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='48π2λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2 − 6 − 96¯ξ + 64λ2 − 26µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='× sinh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� + i csc  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� � +1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='C0r  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='dr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ iπ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3µ4 + 36¯ξµ2 − λ2��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (40)  where the coefficient C0r is given by  C0r = −5  8λ4r4 + 1  8  �  6µ2 + 6λ2 + 36¯ξ + 1  �  λ2r2 − 1  8  �  µ2 + λ2��  µ2 + λ2 + 12¯ξ  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='(41)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='The final results of our evaluation of the unregularized in-vacuum expectation values of the diagonal spacelike com-  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ponents are  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T11  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='= Ω2(τ) H4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�Λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2¯ξ − µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 + 14λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ2 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + 6¯ξµ2 − λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2Λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 54¯ξ2 − 26λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105 − 7µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24 − 8¯ξµ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 18¯ξ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5 λ2 − µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4 + 19λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='72  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='30  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24πλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 35λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 66λ2 − 336¯ξλ2 − 4λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 46λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�cosh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='48π2λ3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 175λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 366λ2 − 2976¯ξλ2 + 136λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 266λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�sinh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� + i csc  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� � +1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='C1r  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='dr − iπ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3µ4 + 36¯ξµ2 − λ2��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (42)  9  where the coefficient C1r is given by  C1r = 35  8 λ4r6 − 1  8  �  70λ4 + 30λ2µ2 + 360¯ξλ2 + 25λ2�  r4 + 1  8  �  39λ4 + 3µ4 + 30λ2µ2 + 396¯ξλ2 + 72¯ξµ2 + 20λ2  + 6µ2 + 432¯ξ2 + 72¯ξ  �  r2 − 1  8  �  4λ4 + 4λ2µ2 + 60¯ξλ2 + 12¯ξµ2 + 2λ2 + 2µ2 + 144¯ξ2 + 24¯ξ  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='(43)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='we also have  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T22  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='=  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T33  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='= Ω2(τ) H4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�Λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2¯ξ − µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 − 2λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ2 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + 6¯ξµ2 + λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2Λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 54¯ξ2 + 2λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='35  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 7µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24 − 8¯ξµ2 + 4¯ξ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5 λ2 − µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4 − 19λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='72  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ 2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5λ2µ2 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16πλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 38λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 24λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 144¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�cosh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='32π2λ3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 178λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 124λ2 − 1024¯ξλ2 + 200λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 220  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�sinh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� + i csc  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� � +1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='C2r  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='dr − iπ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3µ4 + 36¯ξµ2 + λ2��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (44)  where the coefficient C2r is given by  C2r = −C1r  2  − 5  16λ4r4 + 1  16  �  6λ2 − 6µ2 + 36¯ξ + 1  �  λ2r2 + 1  16  �  3µ4 + 2λ2µ2 + 12¯ξλ2 + 36¯ξµ2 − λ2�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (45)  Plugging the resulting expression given in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (32) for the Wronskian of the mode functions Uk into Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (39) and  integrating over momentum phase space, we obtain the unregularized expression for the only nonvanishing off-diagonal  components  �  in  ��T01  ��in  �  =  �  in  ��T10  ��in  �  = Ω2(τ)H4λ  6π2 Λ3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (46)  The expressions (40), (42), (44), and (46) clearly have ultraviolet divergences when Λ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This was expected,  because the expectation values in the Hadamard in-vacuum state suffer from the same ultraviolet divergence properties  as Minkowski spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Construction of the counterterms and adiabatic subtractions  To render the in-vacuum expectation values given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (40), (42), (44), and (46) finite, we provide a set of  needed adiabatic counterterms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The adiabatic regularization method consists of subtracting the appropriate adiabatic  counterterms from the corresponding unregularized expressions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To adjust the set of appropriate counterterms, we will  treat the conformal scale factor Ω(τ), and the electromagnetic vector potential Aµ(τ) as quantities of zero adiabatic  order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' As pointed out by Wald [18], in four dimensions, to obtain a renormalized energy-momentum tensor which  is consistent with the Wald axioms, the subtraction counterterms should be expanded up to fourth adiabatic order;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  see also [1, 2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, to construct the expectation value of the energy-momentum tensor with the desired physical  properties, we expand the subtraction counterterms up to fourth adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  To construct the appropriate  counterterms, we need an expansion for the mode functions up to fourth adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We use the definition  z = 2ikτ to turn the Klein-Gordon Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (26) into the convenient form  d2FA  dτ 2  +  �  ω2  0(τ) + ∆(τ)  �  FA = 0,  (47)  where FA is the positive frequency adiabatic solution and the conformal time dependent frequencies read  ω0(τ) =  �  k2 + 2eA1kr + e2A2  1 + m2Ω2� 1  2 ,  (48)  ∆(τ) = 12¯ξ  � ˙Ω  Ω  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (49)  10  It is then obvious that ω0 is of zero adiabatic order and ∆ is of second adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The adiabatic form of FA is  the Wentzel-Kramers-Brillouin (WKB) solution of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (47).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This WKB solution can be written as  FA(τ) =  1  �  2W(τ)  exp  �  − i  � τ  W(τ ′)dτ ′�  ,  (50)  where W satisfies the exact equation  W2 = ω2  0 + ∆ −  ¨  W  2W + 3 ˙W2  4W2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (51)  To put the solution into the desired form, it is convenient to write W as  W = W(0) + W(2) + W(4),  (52)  where the superscript numbers in parentheses denote the adiabatic order approximation to W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Substituting the  expansion (52) into Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (51), we find the zero adiabatic order approximation  W(0) = ω0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (53)  The next iteration gives the second adiabatic order approximation  W(2) = ∆  2ω0  − ¨ω0  4ω2  0  + 3 ˙ω2  0  8ω3  0  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (54)  Repeated iteration yields the fourth adiabatic order approximation  W(4) = −W(2)2  2ω0  −  ¨  W(2)  4ω2  0  + ¨ω0W(2)  4ω3  0  + 3 ˙ω0 ˙W(2)  4ω3  0  − 3 ˙ω2  0W(2)  4ω4  0  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (55)  It should be remarked that all terms in the adiabatic expansion of W of odd adiabatic order vanish.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Assembling the  pieces given in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (25), (50), and (52)-(55), we find the positive frequency adiabatic solution to fourth adiabatic  order approximation  U [4]  k (x) = Ω−1(τ)  1  √2ω0  �  1 − W(2)  2ω0  − W(4)  2ω0  + W(2)2  2ω2  0  �  exp  �  ik · x − i  � τ  W(τ ′)dτ ′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (56)  We use the superscript symbol [4] to indicate that the cross terms from the field expansion products that are of  adiabatic order greater than 4 are to be discarded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To obtain expansions of the required counterterms to adiabatic  order four, it is only necessary to calculate (36)-(39) with Uk replaced by U [4]  k .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Doing this, we find the counterterm  to adiabatic order four for the timelike component  T [4]  00 = Ω2(τ) H4  8π2  �  Λ4 +  �  µ2 − 6¯ξ + 2λ2  3  �  Λ2 −  �µ4  2 + 6¯ξµ2 − λ2  6  �  log  �2Λ  µ  �  + 72¯ξ2 − λ4  15 + µ2  6 + 9¯ξµ2 + µ4  8  − 2λ2  9  − 2λ2 ¯ξ − λ2µ2  3  − 1  60 +  7λ4  240µ4 +  λ2  30µ2 − 3¯ξλ2  2µ2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (57)  We find the counterterms to adiabatic order four for the diagonal spacelike components  T [4]  11 = Ω2(τ) H4  8π2  �Λ4  3 +  �  2¯ξ − µ2  3 + 14λ2  15  �  Λ2 +  �µ4  2 + 6¯ξµ2 − λ2  6  �  log  �2Λ  µ  �  − 72¯ξ2 − 13λ4  105 − 7µ4  24 − 11¯ξµ2  − 14¯ξ  5 λ2 − µ2  6 + 7λ2  18 − λ2µ2  15  + 1  60 −  7λ4  240µ4 +  λ2  18µ2 + 3¯ξλ2  2µ2  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (58)  and  T [4]  22 = T [4]  33 = Ω2(τ) H4  8π2  �Λ4  3 +  �  2¯ξ − µ2  3 − 2λ2  15  �  Λ2 +  �µ4  2 + 6¯ξµ2 + λ2  6  �  log  �2Λ  µ  �  − 72¯ξ2 + λ4  35  − 7µ4  24 − 11¯ξµ2 + 2¯ξ  5 λ2 − µ2  6 − 7λ2  18 + λ2µ2  5  + 1  60 +  7λ4  720µ4 −  λ2  45µ2 −  ¯ξλ2  2µ2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (59)  11  We obtain the counterterms to adiabatic order four for the only nonvanishing off-diagonal components  T [4]  01 = T [4]  10 = Ω2(τ)H4λ  6π2 Λ3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (60)  Then, the adiabatic regularization procedure is carried out by subtracting the counterterms (57)-(60) from the corre-  sponding unregularized in-vacuum expectation values (40), (42), (44), and (46).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus we obtain our final expression  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='for the timelike component of the regularized energy-momentum tensor  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='T00 =  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T00  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− T [4]  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='00  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='= Ω2(τ) H4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='60 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='7λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='240µ4 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='30µ2 + 3¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2µ2 − 18¯ξ2 − λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='15 + µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12 − 3¯ξµ2 − λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24 − λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24π  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2 − 6 − 96¯ξ + 4λ2 − 26µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�cosh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='48π2λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�45  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2 − 6 − 96¯ξ + 64λ2 − 26µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�sinh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ i csc  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� � +1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='C0r  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='dr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + 6¯ξµ2 − λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='µ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ iπ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3µ4 + 36¯ξµ2 − λ2��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='(61)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='We obtain our final expressions for the diagonal spacelike components of the regularized energy-momentum tensor  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='T11 =  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T11  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− T [4]  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='11  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='= Ω2(τ) H4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='60 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='7λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='240µ4 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='18µ2 − 3¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2µ2 + 18¯ξ2 − 13λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105 + 3¯ξµ2 − 4¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12 − λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8 + λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24πλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 35λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 66λ2 − 336¯ξλ2 − 4λ4 − 46λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�cosh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='48π2λ3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 175λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 366λ2 − 2976¯ξλ2 + 136λ4 − 266λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�sinh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ i csc  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� � +1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='C1r  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='dr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + 6¯ξµ2 − λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='µ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− iπ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3µ4 + 36¯ξµ2 − λ2��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='(62)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='T22 = T33 =  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��T33  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− T [4]  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='33  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='= Ω2(τ) H4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='60 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='7λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='720µ4 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='45µ2 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2µ2 + 18¯ξ2 + λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='35 + 3¯ξµ2 + 2¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12 + λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8 + λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16πλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 38λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 24λ2 − 144¯ξλ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�cosh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='32π2λ3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� 5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='105π−2 − 15 − 132¯ξ + 178λ2 − 11µ2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 124λ2 − 1024¯ξλ2 + 200λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 220  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 λ2µ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�sinh  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πλ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ i csc  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='� � +1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='C2r  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='dr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�µ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + 6¯ξµ2 + λ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='µ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− iπ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3µ4 + 36¯ξµ2 + λ2��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (63)  We see that the nonvanishing unregularized expectation values of the off-diagonal components, given by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (46), are  exactly cancelled by their counterterms (60),  T01 = T10 =  �  in  ��T10  ��in  �  − T [4]  10 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (64)  Thus we have arrived at the desired expressions for the regularized in-vacuum expectation values of all the components  of the energy-momentum tensor, also called the induced energy-momentum tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  12  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='01  10  104  107  10-8  100  1012  1022  1032  1042  �  |T0  0|/H4  �=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='01  �=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1  �=1  �=10  �=100  ξ=0  ξ=  1  6  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The absolute value of T 0  0 component of the induced energy-momentum tensor is plotted in unit of H4 as a function of  the electric field parameter λ = −eE/H2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The graphs correspond to different values of the mass parameter µ = m/H, and the  coupling constant ξ as indicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Both axes have logarithmic scales.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  PROBING THE INDUCED ENERGY-MOMENTUM TENSOR  The nonvanishing components of the induced energy-momentum tensor are given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (61)-(63).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Observe that  all the off-diagonal components of the induced energy-momentum tensor are zero, and the components T22 and T33 are  equal as consequences of the underlying symmetries of the backgrounds (2) and (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Furthermore, since the electric  field background (6) is not invariant under full symmetries of de Sitter spacetime, indeed violates the time reversal  symmetry [51], and causes an electric current along its direction, we observe that T00, T11, and T22 are not equal  to one another.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus we expect that in the limit of vanishing electric field background that the in-vacuum state  possesses the full set of de Sitter invariances, the induced energy-momentum tensor takes the maximally invariant  form under the transformations of de Sitter group, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', must be proportional to the de Sitter metric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By setting λ = 0  in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (61)-(63), which corresponds to vanishing electric field background, the induced energy-momentum tensor  reduced to the form  Tµν = H4  32π2  � 1  15 − 72¯ξ2 − 12¯ξµ2 − 2µ2  3  + µ2�  12¯ξ + µ2��  ψ  �3  2 + γ0  �  + ψ  �3  2 − γ0  �  − log  �  µ2���  gµν,  (65)  where γ0 =  �  (1/4) − µ2 − 12¯ξ is obtained by setting λ = 0 in the definition of γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The expression (65) accords with  the result of computing the renormalized vacuum energy-momentum tensor of a real scalar field in dS4 obtained in  Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [11, 38], except for the overall factor of 2 in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (65).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This factor 2 is consistent with the complex scalar field  as being made of two real scalar fields with the number of degrees of freedom doubling up.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Behavior of the induced energy-momentum tensor  Figures 1-3 provide some useful insight into the general behavior of the induced energy-momentum tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The  absolute values of the expressions (61)-(63) as functions of the electric field parameter λ, for various values of the scalar  field mass parameter µ, and two values of the coupling constant ξ are shown on the graphs in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1-3, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Note especially that the scales are logarithmic on both axes, hence on the graphs zero values of the expressions, where  the signs of the plots change, are displayed as singularities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Therefore, these figures signal that the induced energy-  momentum tensor is analytic and varies continuously with the parameters λ, µ, and ξ, this statement consistent with  the requirements discussed in [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Figures 1-3 also illustrate the outstanding qualitative features of the induced  energy-momentum tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For fixed values of µ and ξ, the absolute values of the nonvanishing components of induced  energy-momentum tensor are increasing functions of λ, but by excluding a neighbourhood of the zero value points this  13  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='01  10  104  107  10-11  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1  109  1019  1029  1039  �  |T1  1|/H4  μ=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='01  μ=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1  μ=1  μ=10  μ=100  ξ=0  ξ=  1  6  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The absolute value of T 1  1 component of the induced energy-momentum tensor is plotted in unit of H4 as a function of  the electric field parameter λ = −eE/H2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The graphs correspond to different values of the mass parameter µ = m/H, and the  coupling constant ξ as indicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Both axes have logarithmic scales.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  behavior is assured.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For fixed values of λ and ξ, the absolute values of the nonvanishing components are decreasing  functions of µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For fixed values of λ and µ, the nonvanishing components do not vary significantly with the parameter  ξ in the range 0 ≤ ξ ≪ λ, µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The qualitative behaviors shown in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1-3 can be given quantitative treatments by  inspection of expressions (61)-(63) in the limiting regimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We concentrate our attention on three regimes of interest:  (1) The strong electric field regime with the criterion λ ≫ max(1, µ, ξ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (2) The heavy scalar field regime with the  criterion µ ≫ max(1, λ, ξ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (3) The infrared regime with the criteria µ ≪ 1, λ ≪ 1, and ξ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Strong electric field regime  In the strong electric field regime λ ≫ max(1, µ, ξ), it is appropriate to find approximate behavior of the induced  energy-momentum tensor in the limit λ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By expanding expressions (61)-(63) around λ = ∞ with µ and ξ fixed,  we find the dominant terms in the components of the induced energy-momentum tensor  T00 = −T11 = 3T22 = 3T33 = −Ω2 H4  8π2  � 7λ4  240µ4  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (66)  Thus, in this regime the absolute value of the nonvanishing components of induced energy-momentum tensor increase  monotonically with increasing λ but decrease monotonically with increasing µ, as we see on the right end of any  graphs in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Heavy scalar field regime  In the heavy scalar field regime µ ≫ max(1, λ, ξ), it is appropriate to find approximate behavior of the induced  energy-momentum tensor in the limit µ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By expanding expressions (61)-(63) around µ = ∞ with λ and ξ fixed,  we find the dominant terms in the components of the induced energy-momentum tensor  T00 = Ω2 H4  8π2  � a  µ2 + b  µ4 + c0λ2  µ4  + O(µ−6)  �  ,  T11 = −Ω2 H4  8π2  � a  µ2 + b  µ4 + c1λ2  µ4  + O(µ−6)  �  ,  T22 = T33 = −Ω2 H4  8π2  � a  µ2 + b  µ4 + c2λ2  µ4  + O(µ−6)  �  ,  (67)  14  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='01  10  104  107  10-9  10  1011  1021  1031  1041  λ  |T2  2|/H4  μ=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='01  μ=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1  μ=1  μ=10  μ=100  ξ=0  ξ=  1  6  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The absolute value of T 2  2 component of the induced energy-momentum tensor is plotted in unit of H4 as a function of  the electric field parameter λ = −eE/H2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The graphs correspond to different values of the mass parameter µ = m/H, and the  coupling constant ξ as indicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Both axes have logarithmic scales.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Recall that T 2  2 = T 3  3 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  where the coefficients a, b, c0, c1 and c2 are given by  a = − 2  315 +  ¯ξ  5 − 72¯ξ3,  b = − 1  210  �  1 − 32¯ξ + 504¯ξ2 − 90720¯ξ4�  ,  c0 = − 1  315 − 7¯ξ  15 + 12¯ξ2,  c1 = − 22  315 + 3¯ξ  5 + 12¯ξ2,  c2 =  2  105 −  ¯ξ  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (68)  The asymptotic forms in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (67) reveal that the induced energy-momentum tensor falls off as H2/m2 in the limit  (m/H) → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, the behavior of the induced energy-momentum tensor is inconsistent with the behavior of the  semiclassical energy-momentum tensor [39, 62] that falls of as exp(−2πm/H) in the heavy scalar field regime where  m ≫ H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A similar feature arises for the induced electric current of both scalar [61] and Dirac [73] fields in dS4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Studies [74, 75] have proposed explanations in physical terms for this feature of the induced electric current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Infrared regime  To find approximate behavior of the induced energy-momentum tensor in the infrared regime, where µ ≪ 1, λ ≪ 1  and ξ = 0, it is appropriate to make Taylor series expansions of the expressions (61)-(63) around µ = 0 and λ = 0,  and set ξ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We find that the dominant terms in the expansions of (61) and (63) are given by  T00 = Ω2 H4  8π2  �61  60 − 17λ2  60µ2 −  7λ4  240µ4 + O  �  λ2, µ2��  ,  (69)  T22 = T33 = −Ω2 H4  8π2  �61  60 + 11λ2  180µ2 +  7λ4  720µ4 + O  �  λ2, µ2��  ,  (70)  which are valid for µ ≪ λ ≪ 1 as well as λ ≪ µ ≪ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The expansion of expression (62) for µ ≪ λ ≪ 1 takes the form  T11 = Ω2 H4  8π2  �299  60 + 7λ2  36µ2 +  7λ4  240µ4 + O  �  λ2, µ2��  ,  (71)  while for λ ≪ µ ≪ 1 it is approximated by  T11 = −Ω2 H4  8π2  �61  60 − 223λ2  36µ2 + 1433λ4  240µ4 + O  �  λ2, µ2��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (72)  15  Observe that all the asymptotic expansions (69)-(71) diverge as m−4 in the exactly massless case, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', m = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We  can understand the origin of these infrared-divergent terms by looking at the counterterms (57)-(59).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' These terms  arise from the contribution of the zero modes in the massless case to the counterterms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' And therefore signal that  for the massless case the method of adiabatic regularization cannot be used because it leads to singularities in the  counterterms, as pointed out in [19, 20, 61].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We emphasize that the result (72) is an approximation valid only for  λ ≪ µ ≪ 1, and hence we cannot use it in the limit of zero mass for a fixed value of λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Trace anomaly  It will be reassuring to do a consistency check, to see that whether the induced energy momentum tensor yields the  well-known predicted trace anomaly for a free, massless, conformally invariant scalar field in dS4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Putting the metric  (2) and components (61)-(63) together,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' we obtain the trace of the induced energy-momentum tensor  T = gµνTµν = H4  8π2  � 1  15 −  7λ4  180µ4 −  λ2  45µ2 + 2¯ξλ2  µ2  − 72¯ξ2 + µ2  3 − 12¯ξµ2 − λ2  6 − 2λ2µ2  3  −  3µ2γ  2π2λ sin  �  2πγ  �  ×  �  2πλ cosh  �  2πλ  �  − sinh  �  2πλ  ��  +  iµ2  2 sin  �  2πγ  �  � +1  −1  �  3λ2r2 − λ2 − µ2 − 12¯ξ  ���  e2πλr + e2iπγ�  × ψ  �1  2 + γ + iλr  �  −  �  e2πλr + e−2iπγ�  ψ  �1  2 − γ + iλr  ��  dr − µ2�  µ2 + 12¯ξ  �  log  �  µ2�  + iπµ2�  µ2 + 12¯ξ  ��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (73)  We see that the trace anomaly of the free, massless, conformally coupled complex scalar field is given by  lim  λ→0 lim  µ→0 lim  ξ→ 1  6  T =  H4  120π2 =  2  2880π2  �1  3R2 − RµνRµν�  ,  (74)  in arriving at the second equality, we have expressed H4 in terms of a combination of the Ricci tensor and the scalar  curvature of dS4 which are given by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (5), to put the result into a familiar form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The trace anomaly (74) is in  agreement with the result of computing the trace anomaly [96] of a free, massless, conformally coupled real scalar  field in dS4, except for the overall factor of 2 in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (74) as explained below Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (65).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  IMPLICATIONS FOR THE INDUCED CURRENT  The generalization of the nonconservation equation (23) for the classical energy-momentum tensor of the scalar field  to the induced energy-momentum tensor Tµν, and the induced current jµ of the scalar field has important implications  for the induced current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Recall that the nonvanishing components of Tµν are given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (61)-(63), and the nonzero  components of Fµν are given by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The only nontrivial relation that arises from Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (23) is obtained by setting  ν = 0, which leads to  ∂0T 00 + HΩ  �  5T 00 + T 11 + T 22 + T 33�  = −Ω−2Ej1,  (75)  where we have used Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (4) and (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The relation (75), along with the relations  ∂0T 00 = −2HΩ(τ)T 00,  T = gµνT µν,  −Ω−2Ej1 = HΩ−1A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='j,  (76)  suffice to show that the timelike component of the induced energy-momentum tensor can be written in terms of the  trace T , and the effective electromagnetic potential energy A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='j as  T00 = 1  4Ω2�  T + A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='j  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (77)  The induced current jµ is defined as the regularized expectation value of the scalar field electric current operator (14)  in the in-vacuum state specified in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (35).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It can be verified that the induced current jµ is conserved and whose  only non-vanishing component is j1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, the induced current flows along the electric field background direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  For convenience we write the induced current as  jµ = Ω(τ)J[n]δ1  µ,  (78)  16  here we use the subscript [n] to indicate the adiabatic order n of the subtracted counterterms to obtain the induced  current J[n].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Comparison of Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (61), (73), and (77) allows us to read off the effective electromagnetic potential  energy A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='j, and then we will use the last relation in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (76) and definition (78) to extract J[4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This gives  J[4] = eH3  8π2  �4¯ξλ  µ2 −  λ  9µ2 − 7λ3  90µ4 + λ  3 log  �  µ2�  − iπλ  3  − 4λ3  15 +  γ  6πλ  �45  π2 − 6 − 96¯ξ + 4λ2 − 8µ2�cosh  �  2πλ  �  sin  �  2πγ  �  −  γ  12π2λ2  �45  π2 − 6 − 96¯ξ + 64λ2 − 8µ2�sinh  �  2πλ  �  sin  �  2πγ  � −  iλ  2 sin  �  2πγ  �  � +1  −1  �  5λ2r4 −  �  1 + 36¯ξ + 6λ2 + 3µ2�  r2  + λ2 + µ2 + 12¯ξ  ���  e2πλr + e2iπγ�  ψ  �1  2 + γ + iλr  �  −  �  e2πλr + e−2iπγ�  ψ  �1  2 − γ + iλr  ��  dr  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (79)  where the subscript [4] indicates J[4] has been derived from the expressions which have been regularized by the  counterterms expanded up to fourth adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This should be clear from Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (61), (77), and (78).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To verify  our result (79), we have evaluated directly the induced current by calculating the expectation value of the current  operator (14) in the in-vacuum state and then subtracting the corresponding counterterms expanded up to fourth  adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The expression for J[4] that follows from this direct analysis reproduces exactly the expression given  by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (79).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  In Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61], the induced current of the massive, minimally coupled ξ = 0, scalar field has been evaluated by  calculating the expectation value of the current operator (14) in the in-vacuum state which is represented by the mode  functions given in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (30) and (31) with ξ = 0 for this case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In order to regularize the expectation value, the method  of adiabatic subtraction was employed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Those authors expanded the required counterterm up to second adiabatic  order that it suffices to remove the divergences and the regularized expression resulting from use of it reduces to the  expected results in the Minkowski spacetime limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We refer to this prescription as minimal subtraction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Furthermore,  they argued that including the contribution of fourth adiabatic order in the counterterm spoils the expected behavior  in the Minkowski spacetime limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Following these restrictions and arguments, it was subsequently found in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61]  that the induced current is given in terms of J[2] as in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (78) by  J[2] = eH3  8π2  �λ  3 log  �  µ2�  − iπλ  3  − 4λ3  15 +  ¯γ  6πλ  �45  π2 + 10 + 4λ2 − 8µ2�cosh  �  2πλ  �  sin  �  2π¯γ  � −  ¯γ  12π2λ2  �45  π2 + 10 + 64λ2 − 8µ2�  × sinh  �  2πλ  �  sin  �  2π¯γ  � −  iλ  2 sin  �  2π¯γ  �  � +1  −1  �  5λ2r4 +  �  5 − 6λ2 − 3µ2�  r2 + λ2 + µ2 − 2  ���  e2πλr + e2iπ¯γ�  × ψ  �1  2 + ¯γ + iλr  �  −  �  e2πλr + e−2iπ¯γ�  ψ  �1  2 − ¯γ + iλr  ��  dr  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (80)  where ¯γ =  �  9/4 − λ2 − µ2 is obtained by setting ξ = 0 in the definition of γ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' and the subscript [2] indicates J[2] has  been regularized by the counterterms expanded up to second adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is important to note that there are  two differences between expressions (79) and (80).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' First, the coupling constant ξ is treated as arbitrary real value  parameter in the expression (79), whereas the expression (80) has been computed for fixed value ξ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Second,  expression (79) contains contributions from the fourth adiabatic order expansion of the counterterm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' With these two  differences, (79) is a generalization of (80).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Therefore, the difference J[4]  �  ξ = 0  �  − J[2] would give only the fourth  adiabatic order contribution of the counterterm to J[4], that is  J[4]  �  ξ = 0  �  − J[2] = −eH3  8π2  � 7λ  9µ2 + 7λ3  90µ4  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (81)  In our subsequent discussion, we demonstrate that the expected behavior of J[4] in Minkowski spacetime is not spoiled  by these fourth adiabatic order contributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Furthermore, we show that these contributions alter the behavior of  the J[4] when compared to J[2], especially in the two regimes of the infrared hyperconductivity and the strong electric  field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Minkowski spacetime limit  Here we explore the behavior of the result (79) in the Minkowski spacetime limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Note that in the limit where the  Hubble constant tends to zero, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=', H → 0 we recover Minkowski spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' As was mentioned in the discussion of  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (81), the difference between the expressions (79) and (80) comes from the contribution of fourth adiabatic order  17  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='001  1  1000  10-6  104  1014  1024  λ  μ=10-3  μ=10-2  μ=10-1  μ=1  μ=5  μ=5  J[4]  J[2]  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Dependence of the absolute values of the normalized induced currents |J[4]|/eH3 (solid curves) and |J[2]|/eH3 (dashed  curves) on the electric field parameter λ = −eE/H2, for the case of minimal coupling ξ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The graphs correspond to different  values of the scalar field mass parameter µ = m/H as indicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Both axes have logarithmic scales.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  in the adiabatic expansion of the counterterm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Comparison of the expressions (79) and (80) shows that these fourth  adiabatic order contributions are  δJ = eH3  8π2  �4¯ξλ  µ2 −  λ  9µ2 − 7λ3  90µ4  �  = − e  8π2  �eE  m2  ��  4¯ξH3 − H3  9 − 7(eE)2  90m2 H  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (82)  where the second equality comes from using the definitions of λ and µ given in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (27).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is clear from the second  equality in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (82) that all these terms vanish in the limit H → 0 for fixed and finite values of E and m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This  observation will automatically insure the validity of (79) in the Minkowski spacetime limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  If the electric field  background E and the scalar field mass m are regarded as fixed and finite, then by taking the limit H → 0 of the  expressions (79), we find  lim  H→0 J[4] =  e3  12π3H E2e− πm2  |eE| ,  (83)  which is exactly the same as the result obtained in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61] for the behavior of J[2], given by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (80), in the  Minkowski spacetime limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It has been argued [61] that in the expanding dS the inverse of the Hubble constant  H−1, in fact, is equivalent to the finite time interval between switching on and off the electric field background in  Minkowski spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By this argument, we can see that the behavior (83) of the induced current in the Minkowski  spacetime limit agrees with the electric current of the charged scalar particles produced by the Schwinger mechanism  in Minkowski spacetime [40, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  A comparison of the result of this article for the induced current J[4] [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (79)] to the result of Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61] for the  induced current J[2] [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (80)] is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The figure is drawn for ξ = 0, and illustrates that, for the light  scalars µ < 1, the induced currents J[4] and J[2] differ considerably in the regime λ ≳ µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Subsequently, we set ξ = 0  and concentrate our attention on the regime λ ≳ µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We examine the behaviors of J[4] and J[2] in the two regimes:  The infrared hyperconductivity with the criterion µ < λ ≲ 1, and the strong electric field λ ≫ max(1, µ, ξ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Behaviors in the infrared hyperconductivity regime  In Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61], it was pointed out that, in the infrared hyperconductivity regime µ < λ ≲ 1, the absolute value of the  induced current J[2] monotonically increases with decreasing the electric field parameter λ, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In this  regime, we can approximate expression (80) by  J[2] ≃ eH3  8π2  �  6λ  λ2 + µ2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (84)  18  From Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 4 it is obvious that in the infrared hyperconductivity regime, the absolute value of the induced current J[4]  reduces to zero at a certain value of the electric field parameter λ∗ which depends on the mass parameter µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Indeed,  the sign of J[4] changes at λ∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This figure also indicates that the absolute value of J[4] is a decreasing function of λ  in the interval µ < λ < λ∗ and is an increasing function for λ > λ∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In the infrared hyperconductivity regime, we can  approximate expression (79) by  J[4] ≃ eH3  8π2  �  − 7λ3  90µ4 − 7λ  9µ2 +  6λ  λ2 + µ2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (85)  This expression has a zero at λ∗ ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In the range of λ > 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ, the dominant contribution to J[4] comes from  the first two terms in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (85) which its absolute value increases with increasing λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, in this range, the infrared  hyperconductivity phenomenon does not occur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' On the other hand, in the interval µ < λ < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ, the dominant  contribution to J[4] comes from the last term in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (85) which increases with decreasing λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, in the interval  µ < λ < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ, the infrared hyperconductivity phenomenon occurs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We therefore conclude that although there exist  a period of the infrared hyperconductivity in our result for the induced current J[4], but now this phenomenon occurs  in the more restricted interval µ < λ < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Behaviors in the strong electric field regime  Figure 4 shows that although the absolute values of the two induced current J[2] and J[4] are increasing functions  of λ in the strong electric field regime λ ≫ max(1, µ, ξ), the induced current J[2] does not depend on the scalar field  mass, whereas the induced current J[4] is proportional to µ−4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We find that, in the limit λ → ∞ for a fixed µ, the  induced current J[4] is given approximately by  J[4] ≃ −eH3  8π2  � 7λ3  90µ4  �  = 7He4  720π2  � E3  m4  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (86)  We observe that the behavior of the induced current J[4] in the Minkowski spacetime limit [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (83)] will be  different from that in the strong electric field limit, see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (86).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Whereas, in [61] it was pointed out that the induced  current J[2] has the same behavior in these two limits, indicated on the right side of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (83).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We note that in  the Minkowski spacetime limit, the electric field strength E, the scalar field mass m, and the coupling constant ξ,  are regarded as fixed and the Hubble constant H, tends to zero.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, in the Minkowski spacetime limit, although  λ = −eE/H2 and µ = m/H tend to infinity, but the ratio λ/µ2 remains finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We also note that in the strong electric  field regime, the Hubble constant H, the scalar field mass m, and the coupling constant ξ, are regarded as fixed and  the electric field strength E, tends to infinity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, in this regime, λ goes to infinity while µ is regarded as a fixed  and finite value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  CONCLUSIONS  The aim of the present research was to examine the induced energy-momentum tensor of a massive, complex  scalar field coupled to the electromagnetic vector potential (7) which describes a uniform electric field background  with a constant energy density in the conformal Poincar´e patch of dS4 where the metric takes the form (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The  dynamics of the complex scalar field is governed by the action (11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The energy-momentum tensor of the scalar field  is not covariantly conserved in the presence of the electromagnetic field, as the consequence of the electromagnetic  interactions, see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (23).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The nonconservation of the scalar field energy-momentum tensor is compatible with the  nonconservation of the electromagnetic field energy-momentum tensor [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (24)], and hence the total energy  momentum tensor of the theory is covariantly conserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We treated the classical gravitational field (2) and the  classical electromagnetic field (7) as fixed field configurations which they are unaffected by the dynamics of the  quantum complex scalar field in response to these backgrounds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We discussed canonical quantization of the scalar  field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The normalized positive and negative frequency mode functions of the scalar field which behave like the positive  and negative frequency Minkowski mode functions in the remote past are given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (30) and (31).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' These mode  functions determine the in-vacuum state of the scalar field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  We calculated the expectation values of all the components of the energy-momentum tensor in the in-vacuum  state of the scalar field;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' the nonzero expectation values have been obtained in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (40), (42), (44), and (46).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is  expected that these expectation values contain ultraviolet divergences, because the expectation values in the Hadamard  in-vacuum state suffer from the same ultraviolet divergence properties as Minkowski spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To render these in-  vacuum expectation values finite, we employed the adiabatic regularization method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To adjust the set of appropriate  19  counterterms, we treated the conformal scale factor and the electromagnetic vector potential as quantities of zero  adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' As pointed out by Wald [18], in four dimensions, to obtain a renormalized energy-momentum tensor  which is consistent with the Wald axioms, the subtraction counterterms should be expanded up to fourth adiabatic  order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Under these assumptions, we then constructed the set of the appropriate adiabatic counterterms, which are  given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (57)-(60).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The adiabatic regularization procedure was carried out by subtracting the counterterms  from the corresponding unregularized in-vacuum expectation values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus we have arrived at our final expressions for  all the nonvanishing components of the induced energy-momentum tensor, which are given by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (61)-(63).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This  research has shown that all the off-diagonal components of the induced energy-momentum tensor are zero, and the  components T22 and T33 are equal as consequences of the underlying symmetries of the backgrounds (2) and (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Furthermore, since the electric field background (6) is not invariant under full symmetries of dS, indeed violates the  time reversal symmetry [51], and causes an electric current along its direction, we observe that T00, T11, and T22 are  not equal to one another.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The research has also shown that in the limit of zero electric field, our result for the induced  energy momentum tensor reduces to the form (65).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The expression (65) accords with the result of computing the  renormalized vacuum energy-momentum tensor of a real scalar field in dS4 obtained in Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [11, 38], except for the  overall factor of 2 in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (65).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This factor 2 is consistent with the complex scalar field as being made of two real  scalar fields with the number of degrees of freedom doubling up.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The absolute values of the expressions (61)-(63) as  functions of the electric field parameter λ, for various values of the scalar field mass parameter µ, and two values of the  coupling constant ξ are shown on the graphs in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1-3, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' These figures signal that the induced energy-  momentum tensor is analytic and varies continuously with the parameters λ, µ, and ξ, this statement consistent with  the requirements discussed in [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For fixed values of µ and ξ, the absolute values of the nonvanishing components  of the induced energy-momentum tensor are increasing functions of λ, but by excluding a neighbourhood of the zero  value points this behavior is assured.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' For fixed values of λ and ξ, the absolute values of the nonvanishing components  are decreasing functions of µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  For a fixed λ and µ, the nonvanishing components do not vary significantly with  the parameter ξ in the range 0 ≤ ξ ≪ λ, µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The qualitative behaviors shown in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1-3 can be given quantitative  treatments by inspection of expressions (61)-(63) in the limiting regimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The examination of the expressions (61)-(63)  has shown that in the strong electric field regime λ ≫ max(1, µ, ξ), the components of the induced energy-momentum  tensor can be approximated by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (66).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In the heavy scalar field regime µ ≫ max(1, λ, ξ), the components can be  approximated according to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (67).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We also found that in the infrared regime, where µ ≪ 1, λ ≪ 1, ξ = 0, the  components can be approximated by Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (69)-(72).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To do a consistency check, we derived the trace anomaly of  the induced energy-momentum tensor for the case of a free, massless, conformally invariant scalar field in dS4;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' see  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (74).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This investigation shows that our result (74) is in agreement with the earlier result of computing the trace  anomaly [96] of a free, massless, conformally coupled real scalar field in dS4, except for the overall factor of 2 in  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (74), as explained below Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (65).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  One of the more significant findings to emerge from this research is that the nonconservation equation (23) implies  the relation (77) between the induced energy-momentum tensor and the induced current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This relation in turn implies  the renormalization condition for the induced current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We derived the expression (79) for the induced current of the  scalar field by using the expressions (61), (73), and relation (77).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This result for the induced current has been derived  from the expressions which have been regularized by the counterterms expanded up to fourth adiabatic order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In  Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61], the induced current of the massive, minimally coupled ξ = 0, scalar field has been evaluated by subtracting  the counterterm expanded up to second adiabatic order;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (80).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In the discussion of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (83), we remarked that  our result for the induced current in the Minkowski spacetime limit agrees with the electric current of the charged  scalar particles produced by the Schwinger mechanism in Minkowski spacetime [40, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A comparison of the result  of this article for the induced current J[4] [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (79)] to the result of Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61] for the induced current J[2] [see  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (80)] is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The figure is drawn for ξ = 0, and illustrates that, for the light scalars µ < 1, the  induced currents J[4] and J[2] differ considerably in the regime λ ≳ µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' From Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 4 it is obvious that in the infrared  hyperconductivity regime µ < λ ≲ 1, the absolute value of the induced current J[4] reduces to zero at a certain  value of the electric field parameter λ∗ which depends on the mass parameter µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We found that in the infrared  hyperconductivity regime, the induced current J[4] can be approximated by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (85) which has a zero at λ∗ ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  In the interval µ < λ < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ, the dominant contribution to J[4] comes from the last term in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (85) which increases  with decreasing λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, the infrared hyperconductivity phenomenon occurs in the interval µ < λ < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We  therefore conclude that although there exist a period of the infrared hyperconductivity in our result for the induced  current J[4], but now this phenomenon occurs in the more restricted interval µ < λ < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='090µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Figure 4 also shows  that the absolute value of the induced current J[4] is an increasing function of λ in the strong electric field regime  λ ≫ max(1, µ, ξ), but decreases as µ−4 with increasing µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We saw that in the limit λ → ∞ for a fixed µ, the induced  current J[4] is given approximately by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (86).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The results of this investigation show that the behavior of the induced  current J[4] in the Minkowski spacetime limit [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (83)] will be different from that in the strong electric field limit,  see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (86).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  This would be a fruitful area for further work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A natural progression of this work is to analyse the backreaction of  20  the induce energy-momentum tensor on the gravitational field of dS4 and the backreaction of the induce current J[4]  on the electromagnetic field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' This is also an issue for future research to explore the induced energy-momentum tensor  of a Dirac field in the context of our discussion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  ACKNOWLEDGMENTS  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' very much appreciate the support by the University of Kashan Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 1143880/1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  Appendix: Evaluation of the momentum integrals over the mode functions  In the appendix we present further supplementary data associated with the calculation of the expressions (36)-(38).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  It is convenient at this stage to switch to the three-dimensional spherical momentum space, and then we can perform  the entire three-dimensional integrals in three-dimensional spherical coordinates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' We introduce a transformation from  the Cartesian momentum coordinates (kx, ky, kz) to the spherical momentum coordinates (k, θ, φ) by equations  kx = k cosθ,  ky = k sin θ cos φ,  kz = k sin θ sin φ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1)  In this coordinates the variable r = kx/k is given by r = cos θ with range −1 ≤ r ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The integration measure is then  d3k = k2 sin θdφdθdk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is useful to covert the variables of integration from the momentum k to the dimensionless  physical momentum p = −kτ, and from the angle θ to the variable r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Thus, the previous expression for the integration  measure may be rewritten as  d3k = −H3Ω3(τ)dφdrp2dp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2)  Accordingly, we use a dimensionless physical momentum cutoff Λ, which is related to the momentum cutoff K as  Λ = −Kτ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' To begin the evaluation of (36)-(38), we change the integration measure according to (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2) and substitute  the expression (30) for Uk(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  After integration over azimuth angle φ and some simplifications, the expressions  (36)-(38) reduce to  �  in  ��T00  ��in  �  = Ω2 H4  8π2  � +1  −1  dr  �  2I1 − 4λrI2 +  �1  4 − γ2 − 18¯ξ + λ2r2�  I3 + 2ℑ  �  I4  �  − 2ℜ  ��  6ξ − 1 − iλr  �  I5  �  + I6  �  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3)  �  in  ��T11  ��in  �  = Ω2 H4  8π2  � +1  −1  dr  �  2r2I1 − 4λrI2 +  ��  4ξ + 1  �  λ2 +  �  4ξ − 1  �  µ2 −  �  4ξ − 1  �  λ2r2  +  �  6ξ − 1  ��  8ξ − 1  ��  I3 − 2ℑ  ��  4ξ − 1  �  I4  �  + 2ℜ  ��  1 − 6ξ + iλr − 4iλrξ  �  I5  �  −  �  4ξ − 1  �  I6  �  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4)  and  �  in  ��T22  ��in  �  =  �  in  ��T33  ��in  �  = Ω2 H4  8π2  � +1  −1  dr  ��  1 − r2�  I1 +  ��  4ξ − 1  ��  λ2 + µ2 − λ2r2�  +  �  6ξ − 1  ��  8ξ − 1  ��  I3 − 2ℑ  ��  4ξ − 1  �  I4  �  + 2ℜ  ��  1 − 6ξ + iλr − 4iλrξ  �  I5  �  −  �  4ξ − 1  �  I6  �  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5)  where ℑ and ℜ stand for the imaginary and real parts of any expressions, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' In these expressions the  momentum integrals over the Whittaker functions have been defined by  I1 = eπλr  � Λ  0  dpp3���Wκ,γ(−2ip)  ���  2  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6)  I2 = eπλr  � Λ  0  dpp2���Wκ,γ(−2ip)  ���  2  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='7)  21  I3 = eπλr  � Λ  0  dpp  ���Wκ,γ(−2ip)  ���  2  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8)  I4 =  �1  4 − γ2 − λ2r2 + iλr  �  eπλr  � Λ  0  dpp2Wκ−1,γ(−2ip)W−κ,γ(2ip),  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='9)  I5 =  �1  4 − γ2 − λ2r2 + iλr  �  eπλr  � Λ  0  dppWκ−1,γ(−2ip)W−κ,γ(2ip),  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='10)  I6 =  ���1  4 − γ2 − λ2r2 + iλr  ���  2  eπλr  � Λ  0  dppWκ−1,γ(−2ip)W−κ−1,γ(2ip).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='11)  The integrals in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6)-(A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='11) are of the same kind of those momentum integrals over the Whittaker functions  which encountered in the calculation of the induced current of a scalar field in two- [60] and four-dimensional [61]  de Sitter spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' The first step in the evaluation of the integrals (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='6)-(A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='11) by the method that explained in  Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' [61], is to plug the Mellin-Barnes representation (28) for the Whittaker function W and make use of the theorem  of residues.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' It is rather straightforward,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' but rather lengthy,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' to show that our final results are  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='I1 = Λ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4 + λr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3 Λ3 + 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 12λ2r2 − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ2 + λr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12γ2 + 20λ2r2 − 7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='128  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='27 + 48γ4 + 560λ4r4 − 120γ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ 480γ2λ2r2 − 520λ2r2�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2Λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 7γ4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='32 + 83γ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='64  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 533  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='96 λ4r4 + 1607  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='192 λ2r2 − 59  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16γ2λ2r2 − 351  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='512 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�55γ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='24  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ 35λ2r2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 355  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='96  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='cos  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ e2πλr�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='256 sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='27 + 48γ4 + 560λ4r4 − 120γ2 + 480γ2λ2r2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 520λ2r2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12)  I2 = Λ3  3 + λr  2 Λ2 + 1  8  �  4γ2 + 12λ2r2 − 1  �  Λ + λr  8  �  12γ2 + 20λ2r2 − 7  �  log  �  2Λ  �  − 37  12λ3r3 + 95  48λr − 5γ2  4 λr  −  �  4γ2 + 15λ2r2 − 4  �  γ  6 sin  �  2πγ  �  �  cos  �  2πγ  �  + e2πλr�  −  iλr  16 sin  �  2πγ  �  �  12γ2 + 20λ2r2 − 7  �  ×  �  π sin  �  2πγ  �  +  �  e2πλr + e−2iπγ�  ψ  �1  2 − γ + iλr  �  −  �  e2πλr + e2iπγ�  ψ  �1  2 + γ + iλr  ��  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='13)  I3 = Λ2  2 + λrΛ + 1  8  �  4γ2 + 12λ2r2 − 1  �  log  �  2Λ  �  − γ2  4 − 7λ2r2  4  + 5  16 −  3γλr  2 sin  �  2πγ  �  �  cos  �  2πγ  �  + e2πλr�  −  i  16 sin  �  2πγ  �  �  4γ2 + 12λ2r2 − 1  ��  π sin  �  2πγ  �  +  �  e2πλr + e−2iπγ�  ψ  �1  2 − γ + iλr  �  −  �  e2πλr + e2iπγ�  ψ  �1  2 + γ + iλr  ��  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='14)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='I4 = − i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 4λ2r2 − 4iλr − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ2 − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 4λ2r2 − 4iλr − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='1 + 2iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='Λ − 3i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='128  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 4λ2r2 − 4iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='− 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 20λ2r2 − 20iλr − 9  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='log  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2Λ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ 79  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='32iλ4r4 + 47  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8 λ3r3 − 409  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='64 iλ2r2 + 39γ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16 iλ2r2 − 109  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='32 λr + 21γ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='λr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ 7i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='32γ4 − 83i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='64 γ2 + 351i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='512 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='γ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4 sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 iλ3r3 + 15λ2r2 + 13  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 iγ2λr − 97  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='8 iλr − 4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='cos  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+ e2πλr�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='256 sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 4λ2r2 − 4iλr − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='4γ2 + 20λ2r2 − 20iλr − 9  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='π sin  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2πγ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='+  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e−2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 − γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='e2πλr + e2iπγ�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='ψ  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='�1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='2 + γ + iλr  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='15)  22  I5 = − i  8  �  4γ2 + 4λ2r2 − 4iλr − 1  �  Λ − 1  8  �  4γ2 + 4λ2r2 − 4iλr − 1  ��  1 + 2iλr  �  log  �  2Λ  �  − 2γ2 − 10λ2r2  − 16  3 iλ3r3 − 4iγ2λr + 20  3 iλr + 3  2 −  iγ  3 sin  �  2πγ  �  �  8γ2 + 12λ2r2 − 18iλr − 8  ��  cos  �  2πγ  �  + e2πλr�  +  i  16 sin  �  2πγ  �  �  4γ2 + 4λ2r2 − 4iλr − 1  ��  1 + 2iλr  ��  π sin  �  2πγ  �  +  �  e2πλr + e−2iπγ�  ψ  �1  2 − γ + iλr  �  −  �  e2πλr + e2iπγ�  ψ  �1  2 + γ + iλr  ��  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='16)  I6 = 1  64  �  16γ4 − 8γ2 + 16λ4r4 + 32γ2λ2r2 + 8λ2r2 + 1  �  log  �  2Λ  �  − 3γ4  16 + 7γ2  32 − 25  48λ4r4 − 7  8γ2λ2r2 − 29  96λ2r2  − 11  256 −  γ  48 sin  �  2πγ  �  �  16γ4 − 8γ2 + 16λ4r4 + 32γ2λ2r2 + 8λ2r2 + 1  ��  12λ3r3 + 20γ2λr + 7λr  ��  cos  �  2πγ  �  + e2πλr�  −  i  128 sin  �  2πγ  �  �  16γ4 − 8γ2 + 16λ4r4 + 32γ2λ2r2 + 8λ2r2 + 1  ��  π sin  �  2πγ  �  +  �  e2πλr + e−2iπγ�  ψ  �1  2 − γ + iλr  �  −  �  e2πλr + e2iπγ�  ψ  �1  2 + γ + iλr  ��  ,  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='17)  where we use log(z) to denote the natural logarithm function, and ψ(z) to denote the digamma function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' By substi-  tuting Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='12)-(A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='17) into expressions (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='3)-(A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='5) and performing the integrals over r, we obtain the results (40),  (42), and (44), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [1] N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Birrell and P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Davies, Quantum Fields in Curved Space (Cambridge University Press, Cambridge, England,  1982).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [2] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker and D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Toms, Quantum Field Theory in Curved Spacetime: Quantized Fields and Gravity (Cambridge  University Press, Cambridge, England, 2009).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [3] R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Wald, Quantum Field Theory in Curved Spacetime and Black Hole Thermodynamics (The University of Chicago  Press, Chicago, 1994).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [4] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 21, 562-564 (1968).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [5] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 183, 1057-1068 (1969).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [6] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' D 3, 346-356 (1971) [erratum: Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' D 3, 2546-2546 (1971)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [7] C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Bernard and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Duncan, Annals Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 107, 201 (1977).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [8] A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Vilenkin, Nuovo Cim.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A 44, 441-450 (1978).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content='  [9] Lowell S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Brown, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' D 15, 1469 (1977).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' D 12, 965-974 (1975).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Critchley, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' D 13, 3224 (1976).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Dowker and R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Critchley, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Adler, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Lieberman and Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Ng, Annals Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' 106, 279 (1977).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Fulling, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Fulling and L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker, Annals Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Fulling, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Parker, and B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Birrell, Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Roy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Lond.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Lond.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Davies, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Fulling, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Christensen and T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Astropart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Trans.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Roy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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+page_content=' Mottola, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DNE2T4oBgHgl3EQf9Qm6/content/2301.04227v1.pdf'}
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diff --git a/DtAzT4oBgHgl3EQfwv4v/content/tmp_files/2301.01726v1.pdf.txt b/DtAzT4oBgHgl3EQfwv4v/content/tmp_files/2301.01726v1.pdf.txt
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+Anisotropic Quantum Hall Droplets
+Blagoje Oblak,1 Bastien Lapierre,2 Per Moosavi,3 Jean-Marie Stéphan,4 and Benoit Estienne5
+1CPHT, CNRS, École Polytechnique, IP Paris, F-91128 Palaiseau, France
+2Department of Physics, University of Zürich, Winterthurerstrasse 190, 8057 Zürich, Switzerland
+3Institute for Theoretical Physics, ETH Zurich, Wolfgang-Pauli-Strasse 27, 8093 Zürich, Switzerland
+4Univ Lyon, CNRS, Université Claude Bernard Lyon 1,
+Institut Camille Jordan, UMR5208, F-69622 Villeurbanne, France
+5Sorbonne Université, CNRS, Laboratoire de Physique Théorique et Hautes Energies, LPTHE, F-75005 Paris, France
+(Dated: January 4, 2023)
+We study two-dimensional (2D) anisotropic droplets of non-interacting electrons in the lowest
+Landau level, confined by trapping potentials whose level curves have an arbitrary shape at large
+distances. Using semiclassical methods, we show that energy eigenstates are localized on equipoten-
+tials of the trap, with angle-dependent local widths and heights. We exploit this one-particle insight
+to deduce explicit formulas for many-body observables in the thermodynamic limit. For instance,
+the droplet’s density falls off at the boundary with an angle-dependent width inherited from that of
+the underlying wave functions, while the many-body current is localized on the edge, to which it is
+tangent. Correlations along the edge are long-ranged, in accordance with the system’s low-energy
+edge modes which are described by a free chiral conformal field theory in terms of the angle variable
+of the trapping potential. These results are likely to be observable in solid-state systems or quantum
+simulators of 2D electron gases with a high degree of control on the confining potential.
+CONTENTS
+I. Introduction
+1
+II. Setup and main results
+2
+III. Anisotropic states from area-preserving maps
+4
+IV. Edge-deformed anisotropic traps
+6
+V. Many-body observables
+10
+VI. Conclusion and outlook
+14
+Acknowledgments
+14
+A. Isotropic droplets
+15
+B. Semiclassical expansion of P V P
+15
+C. The transport equation
+16
+References
+19
+I.
+INTRODUCTION
+Quantum Hall (QH) droplets are mesoscopic two-
+dimensional (2D) electron gases placed in a strong per-
+pendicular magnetic field and confined by some electro-
+static potential: see Fig. 1. They lie at the heart of the
+QH effect [1–3] and provide a key benchmark for topolog-
+ical phases of matter as a whole. In practice, however,
+the vast majority of detailed analytical studies of QH
+droplets are limited to highly symmetric cases, typically
+involving isotropic traps or harmonic potentials that are
+translation-invariant in one direction [4, 5]. This is espe-
+cially troubling as far as edge properties are concerned,
+since these are sensitive to the shape of the trap and
+determine the system’s low-energy excitations [6–10].
+The goal of this paper is to address this lack of analyt-
+ical results by predicting universal aspects of many-body
+observables near the edge of essentially any anisotropic
+droplet. We achieve this by providing general, explicit,
+one-line formulas for the density, current, and correla-
+tions in the regime of strong magnetic fields. We also
+study the corresponding low-energy edge modes, which
+are described by a free-fermion chiral conformal field the-
+ory (CFT) whose Fermi velocity is constant provided dis-
+tances along the boundary are measured by the canonical
+angle variable determined by the potential. These pre-
+dictions are likely to be observable thanks to direct local
+imaging techniques in condensed matter systems [11–16]
+or quantum simulators [17–24].
+This is not the first time such questions appear in the
+literature. Indeed, random potentials with no symme-
+tries are essential to model disorder, whose importance
+for the robustness of QH physics is hard to overstate [25–
+27]. An especially relevant series of works in that con-
+text is [28, 29], which study the density and current of
+QH droplets with arbitrary potentials, at finite temper-
+ature, generally including Landau level mixing, in the
+semiclassical limit of strong magnetic fields and weak
+traps [26, 27]. However, the coherent states used in these
+references do not allow for any resolution at the single-
+particle level, precluding the computation of low-energy
+dynamics and long-range correlations along the bound-
+ary. Our objective here is instead to find explicit wave
+functions that depend on the shape of the edge, and use
+that as a starting point for many-body objects.
+Regarding electronic edge correlations, similar ques-
+tions have been addressed in the context of classical 2D
+arXiv:2301.01726v1  [cond-mat.mes-hall]  4 Jan 2023
+
+2
+Energy
+Fermi
+energy
+Figure 1.
+2D electron droplet (shaded area) placed in a
+strong perpendicular magnetic field and confined by a typical
+anisotropic edge-deformed potential well (10). At leading or-
+der in the thermodynamic limit, the droplet’s boundary (thick
+black curve) coincides with the equipotential of the trap at the
+Fermi energy.
+Coulomb gases, where holomorphic methods play a key
+role [30–32]. More broadly, the results put forward here
+may be seen as microscopic, first-principles derivations
+of quantities that are normally studied within less con-
+trolled approximation schemes in the geometry of the QH
+effect [33–39]. Our hope is thus to build a bridge between
+these theoretical works and concrete observations that
+may soon be accessible in tabletop experiments with a
+high degree of control on the confining potential [23, 24].
+Here is the plan of the paper. To begin, Sec. II sum-
+marizes our methods and results, avoiding all techni-
+cal details. The next two sections are devoted to one-
+body physics in the lowest Landau level: Sec. III first
+discusses generalities on semiclassical holomorphic wave
+functions, while Sec. IV presents a detailed computation
+of the semiclassical energy spectrum in a class of ‘edge-
+deformed’ potentials of particular interest. This finally
+leads to Sec. V, where we investigate many-body densi-
+ties, currents, correlations, and low-energy edge modes in
+anisotropic traps. We conclude in Sec. VI by discussing
+several follow-ups and open questions. To streamline the
+text, non-essential details are deferred to Apps. A–C.
+II.
+SETUP AND MAIN RESULTS
+This section summarizes our methods and key results.
+To start, we describe the general setup: a semiclassi-
+cal limit (strong magnetic field, small magnetic length)
+in the lowest Landau level (LLL) [26, 27, 40]. We then
+introduce edge-deformed potentials and present their ap-
+proximate energy eigenstates, before finally giving simple
+formulas for the corresponding local many-body observ-
+ables and dynamics in the vicinity of the edge. Some of
+these findings are depicted in Fig. 2.
+A.
+Semi-classical limit in the LLL
+This work concerns spin-polarized non-interacting elec-
+trons of mass M and charge q in a 2D plane.
+Each
+electron is governed by a Landau Hamiltonian with an
+anisotropic potential V (x),
+H1-body =
+1
+2M (p − qA)2 + V (x),
+(1)
+where A is the vector potential of the magnetic field
+B = dA. (We view A as a one-form, which simplifies
+some notation but is otherwise inconsequential.) We shall
+assume that V (x) is ‘monotonous’, by which we mean
+that it has a unique global minimum away from which it
+grows monotonously, but it is otherwise general. Conse-
+quently, the level curves or ‘equipotentials’ of V (x) are
+nested and take the form shown in Fig. 2(a). We assume
+throughout that the potential is weak relative to the mag-
+netic field [26–29, 41, 42], and that it is nearly constant
+on length scales comparable to the magnetic length
+ℓ2 ≡ ℏ
+qB > 0.
+(2)
+In that regime, the potential is a small perturbation of
+the pure Landau Hamiltonian ∝ (p−qA)2 and the eigen-
+states of (1) are expected to be well-approximated by
+wave functions in the LLL. For instance, if the potential
+V (x) = V0(r2/2) is isotropic, the eigenstates of (1) have
+some definite angular momentum and reduce at strong
+B to standard LLL wave functions in symmetric gauge:
+φm(x) =
+1
+√
+2πℓ2
+zm
+√
+m!
+e−|z|2/2,
+(3)
+where m ≥ 0 is an integer angular momentum and we
+have introduced the dimensionless complex coordinate
+z ≡ x + iy
+√
+2ℓ .
+(4)
+Each wave function (3) reaches its maximum on the cir-
+cle |z| = √m, away from which it decays in a Gaussian
+manner within a magnetic length. Our goal will be to ob-
+tain similar approximate eigenstates in anisotropic traps,
+using the squared magnetic length (2) as a small expan-
+sion parameter [43]. Equivalently, we shall carry out a
+semiclassical (small ℏ), high field expansion (large B).
+In practice, the projection to the LLL is implemented
+thanks to the (one-body) operator P ≡ �∞
+m=0 |φm⟩⟨φm|,
+whose kernel can be read off from the wave functions (3):
+⟨z, ¯z|P|w, ¯w⟩ =
+1
+2πℓ2 e−(|z|2+|w|2)/2 ez ¯
+w.
+(5)
+This is manifestly Gaussian and reduces to a delta func-
+tion in the formal semiclassical limit ℓ → 0. At small but
+finite ℓ, the projection (5) makes space non-commutative
+in the sense that the LLL-projected position operators
+(x, y) satisfy the Heisenberg algebra
+[PxP, PyP] = iℓ2.
+(6)
+
+3
+���
+���
+���
+x
+x
+x
+y
+y
+y
+√
+N
+−
+√
+N
+−
+√
+N
+√
+N
+(a)
+(b)
+(c)
+x
+x
+x
+y
+y
+y
+ℓ
+√
+2N
+−ℓ
+√
+2N
+−ℓ
+√
+2N
+ℓ
+√
+2N
+Figure 2. (a) A planar plot of the many-body density (14) along with several equipotentials (dashed lines), for a droplet of
+N = 100 electrons confined by the edge-deformed trap of Fig. 1. The constancy of the bulk density and its fall at the boundary
+are manifest. (b) The current’s norm (15) for the same droplet, together with the edge (black line) on which it is localized.
+(c) The correlation function (16) for the same droplet, seen as a function of x2 = (x, y) with x1 = (ℓ
+�
+Nλ(0), 0) denoted by a
+cross and fixed at the edge. Long-range correlations along the boundary are clearly visible.
+One can thus think of the plane R2 as a ‘phase space’
+whose canonical variables are x, y. This interpretation
+pervades much of the QH literature [40, 44–53] and will
+similarly affect our discussion.
+Indeed, projecting the
+Hamiltonian (1) to the LLL and looking for its spectrum
+leads to the eigenvalue equation
+P V P|ψ⟩ = E|ψ⟩,
+(7)
+where the unknowns are the energy E and the quantum
+state |ψ⟩ ∈ LLL. Note that the kinetic term of (1) has
+disappeared in (7): the potential itself plays the role of
+an effective Hamiltonian in the non-commutative phase
+space (x, y).
+Exact solutions of Eq. (7) are generally out of reach,
+so one has to resort to approximations. The semiclassical
+one that we shall use is well known in the QH context
+[26–29, 54, 55]. Accordingly, we will look for solutions of
+Eq. (7) labeled by a large quantum number m ∈ N, seen
+as a generalization of angular momentum.
+This large
+m limit is accompanied by a small ℓ limit, such that
+the area 2πℓ2m remains finite. In that regime, the mth
+eigenstate is approximately Gaussian and localized on an
+equipotential γm of V (x), enclosing a quantized area such
+that the Bohr-Sommerfeld condition holds:
+�
+γm
+x dy = 2πℓ2 m.
+(8)
+Equivalently, the flux of the magnetic field through the
+area enclosed by γm is m times the flux quantum. The
+energy of the mth state is then
+Em = E0
+m + ℓ2E1
+m + O(ℓ4),
+(9)
+where E0
+m = V (γm) is the leading classical approxima-
+tion and the quantum correction E1
+m involves the Lapla-
+cian of the potential and the curvature of the equipo-
+tential γm [54, 55]. Note that the more familiar Wentzel-
+Kramers-Brillouin (WKB) approximation of 1D quantum
+mechanics [56] includes (topological) Maslov corrections
+on the right-hand side of (8); we will find similar correc-
+tions below, although their interpretation as topological
+invariants is prevented by a subtle distinction between
+real and Kählerian polarizations in geometric quantiza-
+tion [54, 55].
+B.
+One-body results
+The semiclassical limit just outlined applies to any
+(monotonous) weak potential. In practice, our main con-
+cern is the physics of QH droplets near the edge, where
+the details of the bulk potential are irrelevant.
+Most
+of our explicit results will therefore be given for ‘edge-
+deformed’ potentials, obtained as follows. Consider any
+monotonously increasing function V0(t) for t ≥ 0, and let
+λ(ϕ) be any strictly positive 2π-periodic function of the
+angle ϕ ∈ [0, 2π); normalize λ so that
+�
+dϕ λ(ϕ) = 4π,
+where we write
+�
+dϕ as a shorthand for
+� 2π
+0
+dϕ. Then
+adopt polar coordinates in the plane such that x + iy =
+r eiϕ and define the potential
+V (r, ϕ) = V0
+� r2
+λ(ϕ)
+�
+.
+(10)
+We refer to this as an edge-deformed trap because it re-
+sults from a deformation r2 �→ r2/λ(ϕ) that changes the
+shape of the boundary of isotropic droplets in a finite
+and smooth way, even in the thermodynamic limit where
+the droplet’s area goes to infinity [57]. In fact, the cor-
+responding infinitesimal transformations are expected to
+
+1
+1
+-
+-
+1
+1
+-
+1
+1
+1
+1
+1
+1
+1
+1
+1
+1
+1
+1
+-4
+be conformal transformations of the edge CFT [58–63].
+The class of potentials (10) is thus exhaustive, at least
+as far as edge effects are concerned.
+The traps (10) turn out to allow for explicit calcula-
+tions of the semiclassical energy spectrum, generalizing
+the known isotropic results reviewed in App. A. Indeed,
+we show in Sec. IV that the corresponding eigenfunc-
+tions, solving (7) in the LLL, are Gaussians localized on
+equipotentials r = ℓ
+�
+mλ(ϕ) at large quantum numbers
+m. They can be written in polar coordinates as
+ψm(x) ∼
+eiΘm(x)
+�
+2πℓ2σ(ϕ)
+e−a2/σ(ϕ)2
+(2πm)1/4 ,
+(11)
+where Θm(x) is a position-dependent phase, a ≡
+�
+r −
+ℓ
+�
+mλ(ϕ)
+��
+ℓ
+�
+λ(ϕ) is a dimensionless radial coordinate
+that measures the distance from the equipotential, and
+σ(ϕ) ≡
+�
+2
+λ(ϕ)
+�
+1 +
+� λ′(ϕ)
+2λ(ϕ)
+�2
+(12)
+is an angle-dependent width. We stress that this exhibits
+the expected ‘quantum smearing’ of wave functions in a
+strong but finite magnetic field [28, 29], which would be
+missed by the leading classical approximations ℓ2 = 0.
+As for the energy of the state (11), its expansion (9)
+up to neglected O(ℓ4) contributions is
+Em ∼ V (γm) + ℓ2
+2 Ωm
+�
+1 +
+�
+1 + Γm
+Ωm
+� � dϕ
+4π λ(ϕ)σ(ϕ)2
+�
+,
+(13)
+where V (γm) = V0
+�
+ℓ2m
+�
+is the leading term, while
+the first quantum correction involves derivatives Ωm ≡
+V ′
+0(ℓ2m) > 0 and Γm ≡ ℓ2m V ′′
+0 (ℓ2m). Each mth energy
+is thus determined by the potential and its derivatives at
+an equipotential that satisfies the quantization condition
+(8), in accordance with general theorems for holomorphic
+WKB theory [54, 55].
+C.
+Many-body results
+Now consider the ground state of a large number
+N ≫ 1 of free spin-polarized electrons, each governed by
+the single-particle Hamiltonian (1). This ground state
+is a Slater determinant of wave functions whose large m
+behavior is the Gaussian (11). As we show in Sec. V,
+the corresponding many-body density, current, correla-
+tions, and low-energy effective action can all be written
+in closed form in terms of λ(ϕ) and the number N of
+fermions. The density ρ(x) = �N−1
+m=0 |ψm(x)|2 thus sat-
+isfies the bulk behavior ρ ∼
+1
+2πℓ2 , while its form near the
+edge is given by a complementary error function:
+ρ(r, ϕ) ∼
+1
+4πℓ2 erfc
+�√
+2 a
+σ(ϕ)
+�
+,
+(14)
+where a ≡
+�
+r − ℓ
+�
+Nλ(ϕ)
+��
+ℓ
+�
+λ(ϕ) is again a dimen-
+sionless radial coordinate, now measuring the distance
+from the edge at redge = ℓ
+�
+Nλ(ϕ).
+As a result, the
+ground state forms a star-shaped droplet whose bound-
+ary has an angle-dependent width (12) inherited from
+that of one-body wave functions. Turning to the current
+J = �N−1
+m=0
+1
+2i(ψ∗
+mdψm − ψmdψ∗
+m − 2iqA|ψm|2), we write
+it as a one-form in polar coordinates to find
+J(r, ϕ) ∼ −
+exp
+�
+− 2a2
+σ(ϕ)2
+�
+(2πℓ2)3/2σ(ϕ)
+�
+ℓ
+√
+N dϕ +
+λ′(ϕ)
+2λ(ϕ)3/2 dr
+�
+.
+(15)
+This is localized on the edge and tangent to it, miss-
+ing the bulk behavior Ji ∝ εij∂jV as expected in the
+LLL [41, 42]. Finally, the two-point correlation function
+C(x1, x2) = �N−1
+m=0 ψ∗
+m(x1)ψm(x2) behaves near the edge
+as
+C(x1, x2) ∼
+eiΘN(x1,x2)
+4πℓ2�
+σ(ϕ1)σ(ϕ2)
+i exp
+�
+−
+a2
+σ(ϕ1)2 −
+b2
+σ(ϕ2)2
+�
+√
+2πN sin
+�� ϕ1
+ϕ2
+dθ
+4 λ(θ)
+�
+(16)
+with a ≡
+�
+|x1| − ℓ
+�
+Nλ(ϕ1)
+��
+ℓ
+�
+λ(ϕ1) and similarly for
+b in polar coordinates (|x1|, ϕ1) and (|x2|, ϕ2), respec-
+tively, while ΘN(x1, x2) is a complicated overall phase.
+Note again the Gaussian localization at the edge, as well
+as the long-range correlator ∝ sin(...)−1 typical of gapless
+fermions. Indeed, we eventually confirm that the under-
+lying low-energy edge modes are described by a chiral
+CFT of free fermions: see the action functional (68) be-
+low. The corresponding Fermi velocity is constant along
+the boundary when measured in terms of the angle vari-
+able of the potential (10), namely θ(ϕ) ≡
+� ϕ
+0 dϕ′ λ(ϕ′)/2.
+III.
+ANISOTROPIC STATES FROM
+AREA-PRESERVING MAPS
+This section presents the WKB ansatz [see (20)] that
+forms the basis of all our later considerations. The struc-
+ture is ultimately quite simple: given a monotonous po-
+tential V (x), we pick one of its equipotentials, γm, with
+quantized area (8). We then build a wave function with
+winding m, perfectly localized on γm, and finally project
+it to the LLL using the operator (5). General theorems
+[54, 55] ensure that LLL-projected eigenstates satisfying
+(7) can indeed be built in this way. The detailed applica-
+tion of this method to edge-deformed traps (10) is given
+in Sec. IV.
+A note: what follows relies on the mathematics of area-
+preserving diffeomorphisms, which is not reviewed in de-
+tail. We refer instead to [57] for an introduction whose
+language is similar to that adopted here. For more gen-
+eral discussions in the symplectic context, see [64, 65].
+A.
+Potentials in action-angle variables
+Let us be more precise about the geometry of the
+setup, remaining at the classical level for now. We pick
+
+5
+a smooth potential V (x) and assume as in Sec. II that it
+is monotonous. Its unique global minimum is thus sur-
+rounded by nested level curves, and one can always find
+an area-preserving deformation of the plane that sends
+each equipotential on a circle [64]. In other words, one
+can find an invertible smooth map F : R2 → R2 with
+unit Jacobian such that
+V
+�
+F(x)
+�
+= V0(r2/2),
+(17)
+where the trap on the right-hand side is isotropic (it only
+depends on r = |x|). If F is the identity (or a rotation
+around the origin), then V was isotropic to begin with
+and its eigenstates satisfying (7) are the standard wave
+functions (3) with definite angular momentum. In the
+more general case of arbitrary V , Eq. (17) suggests using
+F to map the eigenstates (3) on those corresponding to
+our general V (x).
+The existence of F in (17) is guaranteed by the mono-
+tonicity of V , and is equivalent to the existence of glob-
+ally well-defined action-angle variables. In fact, we can
+use this to write F in a more explicit form that will be
+useful below. Let therefore (ℓ2K, θ) be action-angle co-
+ordinates for the potential V (x) [66], where K ≥ 0 is
+dimensionless and θ ∈ [0, 2π) is a genuine angle. They
+are normalized so that ℓ2dK ∧ dθ = dx ∧ dy, which is
+to say that their Poisson bracket reads {ℓ2K, θ} = ℓ2 in
+terms of the phase space (x, y) with bracket (6). Then
+the map (x, y) �→ (ℓ2K, θ) is an area-preserving diffeo-
+morphism in terms of which V (x) = V0(ℓ2K(x)) is in-
+variant under rotations of θ. To be specific, write these
+coordinates as functions K(x, y) and θ(x, y) and let the
+inverse be x = F(K, θ) and y = G(K, θ) for some func-
+tions (F, G); this inverse is nothing but the deformation
+F in (17). In other words, knowing the action-angle vari-
+ables of a potential V allows us to map it on its (unique)
+isotropic cousin V0, which in turn can be used to relate
+the corresponding anisotropic eigenstates to those in (3).
+It should be clear that these considerations apply to
+any monotonous anisotropic trap, in which case one
+generally encounters intricate area-preserving maps with
+complicated action-angle variables. In Sec. IV, we will
+argue that most of these difficulties wash away when
+focusing on edge physics, whereupon the only relevant
+maps are the ‘edge deformations’ mentioned below Eq.
+(10). For now, we remain general and turn to quantum
+considerations.
+B.
+Anisotropic eigenstates
+Using the action-angle variables (ℓ2K, θ) for V (x),
+one can concretize the statements around Eqs. (8)–(9)
+into formulas and eventually obtain anisotropic eigen-
+functions that satisfy (7). Indeed, the Bohr-Sommerfeld
+quantization condition (8) implies that the equipotential
+γm is the set of points in R2 where K = m. Now consider
+the following quantum state, perfectly localized on γm:
+|Ψm⟩ ≡ 2πℓ2
+�
+dθ n(θ) eimθ��F(m, θ), G(m, θ)
+�
+,
+(18)
+where the normalization 2πℓ2 is included for later conve-
+nience, the ‘wave function’ ⟨x|F(m, θ), G(m, θ)⟩ = δ2�
+x−
+F(m, θ)
+�
+is a delta function, and n(θ) is some complex
+periodic function. The latter does not wind upon com-
+pleting one turn in the plane along the equipotential,
+meaning that all the winding of (18) is encoded in the
+phase eimθ.
+We stress that (18) is analogous to the standard WKB
+ansatz ψ(x) ∼ eiS0(x)/ℏeiS1(x) in 1D. Indeed, the phase
+eimθ is the leading classical contribution eiS0/ℏ for m ≫ 1,
+corresponding to the ‘geometrical optics’ approximation
+of the wave function, while n(θ) is the ‘physical optics’
+quantum correction eiS1 that eventually needs to satisfy a
+transport equation in order for the Schrödinger equation
+to hold [56]. The only difference lies in the interpretation
+of areas in the plane as values of an ‘action’, which ul-
+timately stems from the non-commutative geometry (6)
+of LLL physics. Note that n(θ) is the only unknown in
+(18). Indeed, most of the WKB method below will con-
+cern the derivation of a transport equation for n(θ) from
+the requirement that (7) be satisfied.
+Starting from Eq. (18), it is straightforward to build a
+state in the LLL thanks to the projector (5): denoting
+ψm(z, ¯z) ≡ ⟨z, ¯z|P|Ψm⟩,
+(19)
+one finds the wave function
+ψm(z, ¯z) = e−|z|2/2
+�
+dθ n(θ) eimθ
+× e−[F (m,θ)2+G(m,θ)2]/4ℓ2 ez[F (m,θ)−iG(m,θ)]/
+√
+2ℓ.
+(20)
+This is manifestly of the form e−|z|2/2 times a holomor-
+phic function that depends on the action variable ℓ2m
+and the uniformizing map F of Eq. (17). It will be our
+starting point for the semiclassical solution of the eigen-
+value equation (7).
+As a consistency check, note that (20) simplifies for
+isotropic potentials. In that case, action-angle variables
+are just polar coordinates ℓ2K = r2/2 and θ = ϕ, and
+the map in (17) is F(x) = x, merely implementing a
+change from polar to Cartesian coordinates: F(m, θ) =
+ℓ
+√
+2m cos(θ) and G(m, θ) = ℓ
+√
+2m sin(θ). One can then
+verify that (20) with n(θ) = const coincides (up to nor-
+malization) with the standard LLL wave function (3).
+Similarly to that case, any projected wave function (20)
+reaches its maximum on the equipotential γm and is ap-
+proximately Gaussian close to it, as ensured by the kernel
+(5). This will be confirmed explicitly in Sec. IV for edge
+deformations.
+
+6
+C.
+Expanding the eigenvalue equation
+None of what we wrote so far involves a manifest semi-
+classical expansion: it is hidden in the eigenvalue equa-
+tion (7) and the function n(θ) in (20), since n(θ) should
+be expanded as a power series n(θ) = n0(θ) + ℓ2n1(θ) +
+O(ℓ4) (as before, there are no odd powers of ℓ since ℓ2 ∝ ℏ
+is really the semiclassical parameter).
+It is therefore
+worth anticipating the first few terms of the semiclas-
+sical approximation of (7). We stress that the expansion
+below will eventually be limited to the leading order of
+the transport equation, so that only n0(θ) will be calcu-
+lated in the end. In principle, one could of course push
+the expansion to higher orders for more detailed results.
+The semiclassical expansion of the right-hand side of
+(7) is clear: it is given by the large m, small ℓ2 expan-
+sion of the projected wave function (20), including an
+expansion of n(θ). As for the energy, its expansion was
+written in (9). The left-hand side of (7) is more subtle, as
+its semiclassical expansion involves that of the operator
+P V P. The latter is a ‘Berezin-Toeplitz operator’ [54, 55]
+that will play an important role for edge-deformed po-
+tentials, so we now explain its expansion in some detail.
+First, given Cartesian coordinates (x, y), express the po-
+tential in complex coordinates (4) as V (x, y) ≡ V(z, ¯z)
+for some function V(z, ¯w) which is holomorphic in its first
+argument and anti-holomorphic in the second. Then re-
+calling that P is the LLL projector with kernel (5), one
+finds
+⟨z, ¯z|P V P|w, ¯w⟩ =
+1
+2πℓ2 e− 1
+2 (|z|2+|w|2)
+×
+�
+R2 du dv V (u, v) e−|X|2+z ¯
+X+ ¯
+wX
+(21)
+with X ≡ (u + iv)/
+√
+2ℓ similarly to (4). Our task is to
+expand the integral on the right-hand side in the semi-
+classical limit. The key is to assume that the potential
+varies slowly on the scale of the magnetic length [26–29],
+i.e. we choose once and for all a smooth potential V (x),
+independent of ℓ, and let ℓ be small. In that regime, the
+integrals in (21) are approximately Gaussian, which gives
+(see App. A 2)
+⟨z, ¯z|P V P|w, ¯w⟩
+ℓ≪1
+∼
+1
+2πℓ2 e− |z−w|2
+2
+e
+z ¯
+w−¯zw
+2
+×
+�
+V(z, ¯w) + ℓ2
+2 (∇2V )(z, ¯w)
+�
+(22)
+where
+(∇2V )(z, ¯w)
+is
+the
+bicomplex
+function
+that
+corresponds to the Laplacian of the potential,
+i.e.
+(∇2V )(z, ¯w) =
+4
+2ℓ2 ∂z∂ ¯
+wV. This is the standard semiclas-
+sical expansion of a Berezin-Toeplitz operator [54, 55].
+Note the general structure: the entire P V P operator
+boils down to P itself, with kernel (5), multiplied by a
+function that coincides with V at leading order but also
+includes quantum corrections. In the ‘zoomed-out’ limit
+where the kernel of P is a delta function, the first term of
+(22) becomes V(z, ¯z)δ2(z − w, ¯z − ¯w) as expected. More-
+over, for harmonic potentials, the truncated expression
+(22) is actually exact since the next term ∇4V and all
+subsequent ones vanish. This agrees with the common
+lore that ‘WKB is exact for quadratic Hamiltonians’.
+IV.
+EDGE-DEFORMED ANISOTROPIC TRAPS
+Here we apply the WKB ansatz of Sec. III to poten-
+tials (10) with scale-invariant level curves, obtained by
+acting with edge deformations [57] on an isotropic trap.
+As we explain below, these are the most general traps
+one expects to find close to the edge of star-shaped QH
+droplets.
+The plan is as follows.
+First, we introduce
+edge deformations and give a few examples for later ref-
+erence. Second, we apply Eq. (7) to edge-deformed traps
+and expand it in the classical limit (large m, small ℓ2
+with ℓ2m = O(1) kept fixed). We keep track of all terms
+up to order O(ℓ2), so as to capture the leading part of
+the transport equation for the function n(θ) in (18)–(20).
+This eventually yields an explicit energy spectrum [see
+(37)] along with approximately Gaussian eigenfunctions
+[see (43)]. Lastly, we conclude with a consistency check
+by showing that our wave functions reproduce the asymp-
+totic (large m) form of the known LLL-projected spec-
+trum for anisotropic harmonic traps [67–71].
+A.
+Edge deformations
+We have seen in Sec. III that area-preserving defor-
+mations play a key role for the semiclassical solution of
+the eigenvalue equation (7). The group of all such de-
+formations is obviously huge, so it is essential to identify
+the subset of transformations that are likely to be im-
+portant for low-energy physics. In fact, part of this work
+has already been carried out, at least implicitly, in the
+seminal series of papers [58–63], which we now use as a
+basis for the definition of edge deformations. (A similar
+motivation was put forward in [57].)
+Label points on the plane by their polar coordinates
+(r, ϕ), defined as usual by x + iy = r eiϕ.
+Then, the
+boundary of any isotropic QH droplet is located at some
+fixed radius redge = O(ℓ
+√
+N). What is the most general
+area-preserving deformation that preserves this order of
+magnitude? The answer is readily found by realizing that
+the constraint of preserving redge = O(ℓ
+√
+N) is equiva-
+lent, at leading order in 1/N, to the condition that the de-
+formation commutes with overall dilations r �→ const×r.
+The most general deformation satisfying this criterion is
+an edge deformation
+�r2
+2 , ϕ
+�
+�→
+�
+r2
+2f ′(ϕ), f(ϕ)
+�
+,
+(23)
+where f(ϕ) is an (orientation-preserving) deformation of
+the circle, i.e. any smooth map satisfying f(ϕ + 2π) =
+
+7
+f(ϕ) + 2π and f ′(ϕ) > 0. The angle-dependent rescaling
+of r on the right-hand side ensures that the map preserves
+area, and reproduces the argument of the potential (10)
+with λ = 2f ′. Note that the set of maps (23) is isomor-
+phic to the group of diffeomorphisms of the circle, whose
+central extension famously leads to the Virasoro algebra
+encountered in CFT. Indeed, this motivates the state-
+ment in [60, 61] that generators of maps (23) in the QH
+effect produce conformal transformations of edge modes.
+We stress that the subset of transformations (23) orig-
+inates from an asymptotic analysis of the relevant or-
+ders of magnitude. One can undoubtedly consider other
+families of deformations, motivated by different consid-
+erations, but those are irrelevant for our purposes. For
+instance, the transformations r2 �→ r2 + α(ϕ) are crucial
+for the effective low-energy description of QH droplets
+[6, 10, 61], but they are subleading compared to (23) since
+they deform the radius redge = O(ℓ
+√
+N) by terms of order
+O(1/N) instead of O(1). Conversely, one might consider
+‘higher-spin transformations’ [58, 60, 61] that change the
+radius in a dramatic way such as r2 �→ β(ϕ)r4[1+O(1/r)],
+but these stretch QH droplets to an infinite extent in the
+thermodynamic limit, which is why we discard them.
+Let us provide a few examples of edge deformations
+for future reference. First, (23) includes rigid rotations
+around the origin given by f(ϕ) = ϕ + const. A richer
+class is obtained by fixing some positive integer k and
+considering all maps of the form
+eikf(ϕ) = α eikϕ + β
+¯β eikϕ + ¯α
+(24)
+where α, β are complex and satisfy |α|2 − |β|2 = 1. For
+fixed k, such maps span a group locally isomorphic to
+SL(2, R), always containing a subgroup of rigid rotations.
+We will return to these deformations below, since they
+can be seen as Fourier modes for circle diffeomorphisms.
+In particular, setting α = cosh λ and β = sinh λ for some
+real parameter λ turns the map (24) into an analogue of
+a Lorentz boost with rapidity λ. In terms of the bulk
+action (23), any deformation (24) turns a circle into a
+‘flower’ with k petals: see Fig. 5 for k = 3. For k = 2,
+this maps the circle on an ellipse [57], which will be useful
+for anisotropic harmonic traps in Sec. IV E.
+B.
+Edge-deformed potentials
+Given an isotropic potential V0(r2/2), how is it affected
+by an edge deformation (23)? The answer is provided by
+the anisotropic trap (10) with λ(ϕ) = 2f ′(ϕ):
+V (r, ϕ) ≡ V0
+�
+r2
+2f ′(ϕ)
+�
+.
+(25)
+In what follows, we exclusively consider this class of po-
+tentials and refer to them as ‘edge-deformed traps’, for
+the reasons stated above. Having fixed once and for all
+some circle deformation f(ϕ), our goal is to solve the cor-
+responding eigenvalue equation (7) in the classical limit
+of high quantum numbers and small magnetic length.
+We begin by listing the key classical data of the prob-
+lem. The action-angle variables corresponding to (25) are
+(ℓ2K, θ) =
+�
+r2�
+(2f ′(ϕ)), f(ϕ)
+�
+with an inverse given by
+(r2/2, ϕ) =
+�
+ℓ2K/(f −1)′(θ), f −1(θ)
+�
+, where f −1 denotes
+the 1D inverse of f. Points at constant K are equipoten-
+tials, i.e. level curves of (25), each of which is a set of
+points such that
+r2
+2f ′(ϕ) = ℓ2K
+(26)
+with constant K ≥ 0.
+In Cartesian coordinates, this
+is the set of points x =
+�
+2ℓ2Kf ′(ϕ) cos(ϕ), y
+=
+�
+2ℓ2Kf ′(ϕ) sin(ϕ) for ϕ ∈ [0, 2π].
+Equivalently, in
+terms of the angle variable θ = f(ϕ) ∈ [0, 2π], the equipo-
+tential is
+x =
+�
+2ℓ2K
+(f −1)′(θ) cos(f −1(θ)) ≡ F(K, θ),
+y =
+�
+2ℓ2K
+(f −1)′(θ) sin(f −1(θ)) ≡ G(K, θ),
+(27)
+where the notation (F, G) was introduced in Sec. III A.
+Note that we will eventually focus on the regime where
+K ≫ 1 is very large in such a way that the dimensionful
+area 2πℓ2K be an O(1) quantity as ℓ → 0.
+Moving just slightly away from the classical regime, we
+have seen in Sec. III that the expansion of the operator
+P V P involves a bicomplex potential function V(z, ¯w). In
+the case of edge-deformed potentials (25), with the con-
+ventions used there and above for complex coordinates,
+one finds
+V(z, ¯w) = V0
+�
+ℓ2
+z ¯w
+f ′� 1
+2i log[z/ ¯w]
+�
+�
+.
+(28)
+Note that this only makes sense for z and w close to each
+other, otherwise taking z → e2πiz affects the argument
+of f ′ on the right-hand side. By contrast, when z and w
+remain close, taking z → e2πiz also requires w → e2πiw,
+and this time the angle
+1
+2i log[z/ ¯w] is indeed invariant.
+Finally, the expansion (22) also involves the complexi-
+fied Laplacian of the potential, but only its real value will
+be relevant at the order studied here. Let us therefore
+express the Laplacian of (25) in polar coordinates:
+∇2V = 1
+f ′
+�
+2 − 1
+2
+f ′′′
+f ′ + f ′′2
+f ′2
+�
+V ′
+0
+�
+r2/2f ′�
++ r2
+f ′2
+�
+1 + f ′′2
+4f ′2
+�
+V ′′
+0
+�
+r2/2f ′�
+.
+(29)
+Here the prime means differentiation with respect to the
+argument, namely ϕ for f(ϕ) and r2/2 for V0(r2/2). We
+shall rely on (28) and (29) below, since they directly affect
+the eigenvalue equation (7).
+
+8
+C.
+Eigenvalue equation and energy
+Having studied the potential (25), let us turn to the
+quantum state meant to solve the eigenvalue equation
+(7). As in Sec. III B, we begin by building a state (18)
+that is perfectly localized on the equipotential, project
+to the LLL using the operator (5), and obtain the wave
+function (20) that now reads
+ψm(z, ¯z) = e−|z|2/2
+�
+dϕ f ′(ϕ) n(f(ϕ))
+× exp
+�
+imf(ϕ) − 1
+2mf ′(ϕ) + z
+�
+mf ′(ϕ) e−iϕ�
+,
+(30)
+where we changed variables using θ = f(ϕ). It remains to
+show that this solves the eigenvalue equation (7) for edge-
+deformed traps (25) in the semiclassical regime, provided
+the function n(θ) satisfies a suitable transport equation.
+The latter is derived by expanding the energy (9) and
+the potential (22) to get
+0 =
+�
+dϕ f ′(ϕ) n(f(ϕ))
+× exp
+�
+imf(ϕ) − 1
+2mf ′(ϕ) + z
+�
+mf ′(ϕ) e−iϕ�
+×
+�
+V
+�
+z,
+�
+mf ′(ϕ) e−iϕ�
++ ℓ2
+2 ∇2V − E0
+m − ℓ2E1
+m
+�
+(31)
+where V(z, ¯w) is the bicomplex function (28) and the
+equation holds up to neglected O(ℓ4) corrections.
+At
+leading order in the classical limit, the potential expan-
+sion (22) boils down to ⟨z|P V P|w⟩ ∼ V(z, ¯z)δ2(z − w),
+so (31) merely states that E0
+m = V0(ℓ2m) = V (γm). The
+issue is to find the two remaining unknowns: the function
+n(f(ϕ)) and the first-order energy correction E1
+m.
+To determine these, the crucial step is to evaluate (31)
+along the equipotential (26) labeled by K = m, i.e. for
+z =
+�
+mf ′(α) eiα with α ∈ [0, 2π), where as usual we
+assume m ≫ 1. Indeed, if (31) holds on a level curve,
+then it holds for all z by holomorphicity. This is writ-
+ten in more detail in App. C, where we show that the
+integrand of (31) has a saddle point at ϕ = α, eventu-
+ally resulting in a transport equation for the unknown
+function n. Here we skip the computation and analyse
+separately the real and imaginary parts of the transport
+equation. We start with the real part, which will allow
+us to deduce the LLL-projected energy spectrum. The
+imaginary part is postponed to Sec. IV D, where we also
+display the resulting nearly Gaussian wave functions.
+Let Φ(ϕ) denote the phase of n(f(ϕ)) ≡ N(ϕ) eiΦ(ϕ).
+Then the real part of the transport equation [see (C17)]
+yields
+Φ′(ϕ) = E1
+m
+Ωm
+f ′(ϕ) − 1
+2
+� Γm
+Ωm
++ 1
+��
+1 + f ′′(ϕ)2
+4f ′(ϕ)2
+�
+− 1
+2 + ∂ϕ
+� f ′′(ϕ)
+8f ′(ϕ)
+�
++ 1
+2
+∂ϕ[f ′′(ϕ)/2f ′(ϕ)]
+1 + f ′′(ϕ)2/4f ′(ϕ)2 ,
+(32)
+where E1
+m is the first order correction to the energy (9)
+and we introduced the parameters
+Ωm ≡ V ′
+0(ℓ2m) > 0,
+Γm ≡ ℓ2m V ′′
+0 (ℓ2m).
+(33)
+In many-body droplets with N electrons, these will re-
+spectively measure the Fermi velocity and the curvature
+of the potential at the Fermi surface when m = N. Note
+that all terms in (32) are total derivatives save for the
+factor 1 + [f ′′/2f ′]2, so the solution is
+Φ(ϕ) = E1
+m
+Ωm
+f(ϕ) − 1
+2
+� Γm
+Ωm
++ 1
+� � ϕ
+0
+dθ
+�
+1 + f ′′(θ)2
+4f ′(θ)2
+�
+− ϕ
+2 + f ′′(ϕ)
+8f ′(ϕ) + 1
+2 arctan
+� f ′′(ϕ)
+2f ′(ϕ)
+�
++ const.
+(34)
+This turns out to imply a quantization condition for en-
+ergy. Indeed, when we initially introduced the function
+n(θ) in (18), we mentioned that it must have a vanishing
+winding number along the equipotential, so that all the
+winding of the wave function is contained in the expo-
+nential factor eimθ. The phase Φ(ϕ) must therefore be
+strictly 2π-periodic, i.e. Φ(2π) = Φ(0). Using (34), this
+fixes the first quantum correction of the energy (9):
+E1
+m
+Ωm
+= 1
+2 +
+� Γm
+Ωm
++ 1
+� � dϕ
+4π
+�
+1 + f ′′(ϕ)2
+4f ′(ϕ)2
+�
+.
+(35)
+The latter generally generally depends on m through Γm
+and Ωm in (33).
+A simplification only occurs in ‘har-
+monic’ setups where Γm = 0 and the right-hand side of
+(35) is an f-dependent constant, for all m [72]. In any
+case, the full mth energy (9) in the semiclassical limit can
+be written as
+Em ∼ V0
+�
+ℓ2m
+�
++ ℓ2
+2
+�
+Ωm +
+�
+Γm + Ωm
+� � dϕ
+2π
+�
+1 + f ′′(ϕ)2
+4f ′(ϕ)2
+��
+,
+(36)
+reproducing the result announced in (12)–(13) with λ =
+2f ′ and generalizing the isotropic value obtained for
+f ′ = 1 [see (A3)]. The leading-order Bohr-Sommerfeld
+quantization condition (8) is manifestly satisfied, while
+the first quantum correction can be expressed in terms
+of a Maslov-like shift and an integral of the Laplacian,
+confirming the general result in [55]:
+Em = V0
+�
+ℓ2�
+m + 1
+2
+��
++ ℓ2
+4
+� dϕ
+2π f ′(ϕ)∇2V
+��
+r2=2ℓ2(m+1/2)f ′(ϕ) + O(ℓ4).
+(37)
+(In the language of [55], our ‘Maslov-like’ term actually
+stems from an integral of the curvature of γm.) It now
+remains to write the corresponding wave functions.
+D.
+Gaussian wave functions
+As above, write n(f(ϕ)) = N(ϕ) eiΦ(ϕ) for the un-
+known function of the WKB ansatz, with a norm N(ϕ) =
+
+9
+|n(f(ϕ))|.
+Then the imaginary part of the transport
+equation [see (C18)] can be recast into
+N ′(ϕ)
+N(ϕ) = 1
+4∂ϕ log
+�
+1
+f ′(ϕ)
+�
+1 + f ′′(ϕ)2
+4f ′(ϕ)2
+��
+,
+(38)
+which remarkably has the form of an overall logarithmic
+derivative. The general solution is thus
+��n
+�
+f(ϕ)
+��� = N0
+�
+1
+f ′(ϕ)
+�
+1 + f ′′(ϕ)2
+4f ′(ϕ)2
+��1/4
+,
+(39)
+where the normalization N0 will soon be fixed. Note the
+exponent 1/4, typical of WKB approximations [56].
+We can now use (39) to evaluate approximate eigen-
+functions (30) near their maximum, i.e. close to the
+equipotential (C2). To see this, zoom in on the equipo-
+tential by writing
+z ≡
+�√m + a
+��
+f ′(α) eiα
+(40)
+for m ≫ 1 and some finite a. The integral (30) then has
+a unique saddle point at ϕ = α−iδ1/√m+O(1/m), with
+δ1 = a
+�
+1 − i f ′′(α)
+2f ′(α)
+�−1
+. The saddle-point approximation
+of the wave function (30) thus yields
+ψm(z, ¯z) ∼
+1
+√
+2πℓ2
+1
+(2πm)1/4 eimf(α)+iΦ(α)
+×
+1
+�
+σ(α)
+exp
+�
+�− f ′(α) a2
+1 − i f ′′(α)
+2f ′(α)
+�
+� ,
+(41)
+where we used Eqs. (34)–(39) for the phase and norm of
+n(f(α)), fixed the integration constant in (39) to N0 =
+1
+2πℓ( m
+2π)1/4, and introduced the ubiquitous width
+σ(ϕ)2 ≡
+1
+f ′(ϕ)
+�
+1 + f ′′(ϕ)2
+4f ′(ϕ)2
+�
+.
+(42)
+This is the angle-dependent variance of the probability
+density of (41), written in (12) in terms of λ = 2f ′. In-
+deed, one has
+|ψm(z, ¯z)|2 ∼
+1
+2πℓ2
+e−2a2/σ2(α)
+√
+2πm σ(α),
+(43)
+which
+satisfies
+the
+desired
+normalization
+condition
+�
+d2x |ψ|2 = 1. Note that Eq. (41) reproduces the wave
+function stated in (11), once more with λ = 2f ′ and now
+involving the phase
+Θm(x) = mf(ϕ) + Φ(ϕ) −
+a2f ′′(ϕ)
+2f ′(ϕ)σ(ϕ)2 .
+(44)
+The Gaussian behavior of LLL-projected is thus mani-
+fest, as anticipated at the end of Sec. III B for the gen-
+eral WKB ansatz (20). It is illustrated in Fig. 3 for two
+choices of the confining potential (25). Finally, (41) gen-
+eralizes the behavior of isotropic states (3) [see (A1)], in-
+cluding the O(1/√m) contribution that we did not state
+here but that can be computed by incorporating the next
+order term δ2/m for the saddle point and repeating the
+analysis [73].
+Out[� ]=
+0
+0.2
+0.4
+0.6
+0
+1
+|ψm|2
+Figure 3. The density of a wave function (41) at m = 30 in an
+edge-deformed trap (25). The Gaussian behavior is manifest,
+as is the angle-dependent ‘roller coaster’ predicted by (43).
+Left: Elliptic potential given by (25) with f of the form (24)
+and k = 2. Right: Same edge-deformed trap as in Figs. 1–2.
+E.
+Comparison with elliptic wave functions
+To conclude this section, we now focus on the ‘flower’
+deformations (24) and show that the resulting transport
+equation is integrable: both the phase (34) and the norm
+(39) can be expressed in terms of elementary functions.
+These results are valuable in themselves since flower maps
+are the simplest edge deformations—they are analogues
+of Fourier modes for circle diffeomorphisms—, but also
+because their special case k = 2 reproduces known wave
+functions in elliptic harmonic traps [68, 74], providing an
+important benchmark for our WKB approach.
+Consider first the deformation (24) with α = cosh λ
+and β = sinh λ for an arbitrary integer k and a real pa-
+rameter λ. Then the energy quantization condition (35)
+can be integrated exactly, yielding
+E1
+m
+Ωm
+= 1
+2 + 1
+2
+�
+1 + Γm
+Ωm
+��
+1 + k2
+4
+�
+cosh(2λ) − 1
+��
+. (45)
+As for the solution of the transport equation, consisting
+of the phase (34) and norm (39), it is found to be
+n(θ) = N0 e
+i
+8
+Γm
+Ωm k sin(kθ) sinh(2λ)e
+i θ
+2
+�
+(
+Γm
+Ωm +1)
+�
+1− k2
+4
+�
++1− k
+2
+�
+×
+�cosh λ + eikθ sinh λ
+eikθ cosh λ + sinh λ
+� k2−4
+8k (1+ Γm
+Ωm )− 1
+2k + 1
+4
+×
+�
+−4eikθ + (e2ikθ − 1)k sinh(2λ)
+eikθ cosh λ + sinh λ
+(46)
+up to an overall constant phase.
+Note that (46) depends in a non-trivial way on the po-
+tential derivatives (33), with some simplification in the
+‘harmonic’ regime Γm = 0. Let us therefore apply Eqs.
+(45)–(46) to the case of an elliptic potential k = 2 with
+constant stiffness Ωm = Ω > 0 (hence Γm = 0). The cor-
+responding edge deformation (23) maps the isotropic har-
+monic potential V0(x) = Ω r2/2 on its anisotropic cousin,
+V (x) = Ω e−2λx2 + e2λy2
+2 cosh(2λ)
+,
+(47)
+
+10
+whose equipotentials are ellipses rather than circles. The
+energy correction (45) then becomes E1
+m =
+1
+2Ω[1 +
+cosh(2λ)] and the solution (46) of the transport equation
+can be written as
+n(θ) = N0
+�
+cosh λ − e2iθ sinh λ.
+(48)
+It is straightforward to use this data to obtain the elliptic
+version of the normalized Gaussian wave function (41):
+ψm(z, ¯z) ∼
+�2π
+m
+�1/4
+1
+2πℓ
+eimθ
+√
+cosh λ − e−2iθ sinh λ
+× exp
+�
+−e2iθ + tanh(λ)
+e2iθ − tanh(λ)a2
+�
+.
+(49)
+Crucially, the latter coincides with the large m approxi-
+mation of the exact LLL-projected eigenstates of the har-
+monic potential (47), as can be verified thanks to known
+asymptotic formulas for Hermite polynomials [68]. This
+is actually true even at subleading order in 1/√m, which
+we omit here for brevity.
+V.
+MANY-BODY OBSERVABLES
+This section finally applies the results of Secs. III–IV
+to fully-fledged QH droplets consisting of a large num-
+ber N ≫ 1 of electrons.
+Specifically, we exploit our
+insights on near-Gaussian single-particle wave functions
+(41) to compute many-body observables and read off the
+universal shape-dependent effects implied by the width
+(42). The density is treated first: it equals
+1
+2πℓ2 in the
+bulk, then drops to zero as an error function at the edge
+redge = ℓ
+�
+2Nf ′(ϕ). We then turn to the current and
+show that it is localized as a Gaussian on the edge, to
+which it is tangent.
+Third, correlations near the edge
+are found to display the usual power-law behavior of free
+fermions, dressed by radial Gaussian factors.
+This re-
+duces to known expressions in isotropic traps [59] and in
+the case of flower deformations (24) with k = 2, where
+one recovers the elliptic results of [68, 74]. Finally, the
+radial behavior of correlations is shown to be consistent
+with the effective low-energy field theory of edge modes:
+we derive it microscopically and obtain a chiral CFT in
+terms of the angle variable on the boundary.
+A.
+Density
+Consider a QH droplet of N ≫ 1 non-interacting 2D
+electrons subject to the Hamiltonian (1), with a very
+strong magnetic field B = dA and a weak edge-deformed
+potential (25). The ground state of this many-body sys-
+tem is a Slater determinant of the wave functions ψm for
+occupied states m = 0, 1, . . . , N −1, where we recall that
+m is a quantized action variable generalizing angular mo-
+mentum (see the red dots in Fig. 4). Each ψm yields a
+m
+Energy
+◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦••••
+N
+Fermi energy
+••••••••◦◦◦◦◦◦· · ·
+◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦· · ·
+2Λ
+Figure 4. The one-body spectrum (37), where the states that
+are occupied in the many-body ground state are highlighted in
+red and those that contribute to the low-energy Hamiltonian
+(64) are filled (black for ‘particles’, red for ‘holes’). The cutoff
+Λ is large but much smaller than N in the sense that Λ = O(1)
+in the thermodynamic limit.
+single-particle probability density |ψm(x)|2, the sum of
+which gives the many-body density
+ρ(x) =
+N−1
+�
+m=0
+|ψm(x)|2.
+(50)
+While WKB theory does not give access to the form of ψm
+at low m, large values of m should be correctly captured
+by the analysis of Sec. IV, in which case the one-body
+density is approximately Gaussian and given by (43). We
+now exploit this Gaussian form to evaluate the many-
+body density, both in the bulk and close to the edge.
+(Some technical details are highlighted along the way, as
+the same method will later allow us to study the many-
+body current and correlations.)
+The key point is that each wave function (43) is local-
+ized on an equipotential of V (x) with area 2πℓ2m, so the
+density close to some equipotential |z| = const ×
+�
+f ′(ϕ)
+only receives sizeable contributions from wave functions
+whose quantum number is close to |z|2/f ′(ϕ). Accord-
+ingly, the bulk density for 1 ≪ |z| ≪
+√
+N is obtained by
+letting the upper summation bound of (50) go to infinity
+and writing the approximate density as
+ρ(x) ∼
+1
+2πℓ2
+∞
+�
+m=m0
+e
+−
+2
+σ2(ϕ)
+�
+|z|
+√
+f′(ϕ) −√m
+�2
+√
+2πm σ(ϕ)
+,
+(51)
+where the lower summation bound m0 ≫ 1 is irrele-
+vant as long as it is much smaller than |z|2, and σ(ϕ) is
+the angle-dependent width (42). At large |z|, the Euler-
+Maclaurin formula allows us to approximate the sum over
+m by a (Gaussian) integral over √m. This yields the ex-
+pected density
+ρ(x) ∼
+1
+2πℓ2
+(52)
+in the bulk of a QH droplet with filling fraction ν = 1.
+An analogous argument can be carried out close to
+the droplet’s edge, with one key difference: the upper
+summation bound of (50) is now crucial. Thus, letting
+|z| =
+�√
+N + a
+�
+f ′(ϕ) with finite a in the large N limit
+
+11
+and using once more the approximate Gaussian behavior
+(43), the density (50) near the edge behaves as
+ρ(x) ∼
+1
+2πℓ2
+∞
+�
+k=1
+e
+−
+2
+σ2(ϕ)
+�
+a+
+k
+2
+√
+N
+�2
+√
+2πN σ(ϕ)
+,
+(53)
+where we changed variables as m ≡ N − k with k =
+O(
+√
+N) at large N and only kept track of leading-order
+terms. For N ≫ 1, the sum over k can once more be
+converted into an integral, now over k/2
+√
+N. This yields
+the asymptotic behavior
+ρ(r, ϕ) ∼
+1
+4πℓ2 erfc
+�
+1
+σ(ϕ)
+r − ℓ
+�
+2Nf ′(ϕ)
+ℓ
+�
+f ′(ϕ)
+�
+(54)
+where erfc denotes the complementary error function and
+the width (42) is inherited from that of LLL wave func-
+tions. This is a remarkably explicit result, announced in
+(14) with λ = 2f ′. It confirms that the density is roughly
+constant and equal to (52) in the bulk, then drops to zero
+within a distance of the order of the magnetic length (2)
+around the edge at r = ℓ
+�
+2N f ′(ϕ). See Figs. 2(a)–5(a).
+We stress that, in contrast to wave functions, the den-
+sity (54) only depends on the potential near the edge of
+the droplet: bulk deformations of the potential do not af-
+fect the quantized bulk density (52) in the limit of strong
+magnetic fields. In this sense, (54) is a universal formula
+for the density of any QH droplet of LLL states whose
+edge traces an equipotential of the form r2 = 2ℓ2N f ′(ϕ).
+It would be instructive to probe this local density in mod-
+ern quantum simulators [21–24].
+Note that the leading-order formula (54) receives a
+number of subleading corrections that can be systemati-
+cally computed in our formalism; these are omitted here
+for brevity. A related comment is that the bulk value
+density (52) is only valid at extremely strong magnetic
+fields, which stems from the simplification provided by
+the LLL projection. The actual density profile depends
+on the gradient of the potential, but this involves higher
+Landau levels that are beyond our scope [28, 29].
+B.
+Current
+The current of a droplet of N ≫ 1 electrons can simi-
+larly be evaluated as a sum over single-particle currents.
+To this end, recall that the gauge-invariant one-body
+probability current of a charged wave function ψ with
+mass M is a one-form ℏ j/M given by
+j = 1
+2i
+�
+ψ∗dψ − ψdψ∗ − 2iq
+ℏA|ψ|2�
+,
+(55)
+where the first term is only sensitive to the phase of ψ
+and A = 1
+2Br2 dϕ = ℏ
+q |z|2 dϕ in symmetric gauge. Thus,
+the many-body current of a Slater determinant of the
+occupied states ψm with m = 0, . . . , N − 1 is
+J =
+N−1
+�
+m=0
+jm,
+(56)
+where jm is the single-particle current (55) of each ψm.
+As before, the WKB approximation does not give ac-
+cess to wave functions for small m, but this is unim-
+portant close to the edge. In that regime, we have al-
+ready gathered all ingredients needed to evaluate the
+currents (55) up to small quantum corrections: the one-
+body density is given by (43), while the derivative of
+the phase is contained in (41) and the phase transport
+equation (32).
+In practice, the WKB phase Φ turns
+out to be negligible at leading order, and the only rel-
+evant parts of the phase are those already visible in (41):
+the (fast) phase eimf(ϕ) together with the contribution
+from A =
+�
+ℏ|z|2/q
+�
+dϕ eventually gives rise to the lead-
+ing ϕ component of the current, while the (slow) phase
+e−i[f ′′(ϕ)/2f ′(ϕ)]a2/σ2 yields its radial component that is
+non-zero whenever f ′′(ϕ) ̸= 0.
+Starting from these facts, it is straightforward to adapt
+the method of Sec. V A to the many-body current (56).
+Writing |z| =
+�√
+N +a
+��
+f ′(ϕ), the sum over m ≡ N −k
+becomes an integral over k/(2
+√
+N) = O(1), which yields
+the leading order result quoted in (15) with λ = 2f ′:
+J(r, ϕ) ∼ −
+e
+−
+2a2
+σ(ϕ)2
+(2πℓ2)3/2σ(ϕ)
+ℓ
+�
+2Nf ′(ϕ) dϕ + f ′′(ϕ)
+2f ′(ϕ) dr
+�
+2f ′(ϕ)
+(57)
+where a =
+�
+r−ℓ
+�
+2Nf ′(ϕ)
+��
+ℓ
+�
+2f ′(ϕ) and σ(ϕ) is given
+by (42). Both components in (57) receive subleading cor-
+rections that are omitted here. In particular, there is an
+O(1) term in Jϕ that is non-zero on the edge, even in the
+isotropic case f ′ = 1. The computation of that term re-
+quires the O(1/√m) correction that was omitted in (43).
+Using the metric ds2 = dr2 + r2dϕ2, one verifies that
+the one-form ℓ√2N f ′ dϕ+(f ′′/2f ′) dr in (57) is the dual
+of a vector tangent to the equipotential at the droplet’s
+edge [75]. Moreover, the norm squared of (57) is
+∥J(r, ϕ)∥2 ∼
+1
+2(2πℓ2)3 exp
+�
+−2
+�
+r − ℓ
+�
+2Nf ′(ϕ)
+�2
+ℓ2σ(ϕ)2f ′(ϕ)
+�
+,
+(58)
+showing that the current has a constant maximum along
+the edge but a varying width: see Fig. 5.
+Similarly to the density, it is important to remember
+that the LLL projection misses some important physics.
+Indeed, the actual bulk current is the symplectic gra-
+dient of the confining potential multiplied by the Hall
+conductance [28, 29, 41, 42].
+No such effect occurs in
+(57) because it requires higher Landau levels, which are
+beyond our scope.
+C.
+Correlations
+The methods that we have applied to density and cur-
+rent can also be used to compute electronic correlations
+near the edge. Indeed, consider as before an anisotropic
+droplet whose occupied one-body states have quantum
+
+12
+���
+���
+���
+x
+x
+x
+y
+y
+y
+√
+N
+−
+√
+N
+−
+√
+N
+√
+N
+(a)
+(b)
+(c)
+x
+x
+x
+y
+y
+y
+ℓ
+√
+2N
+−ℓ
+√
+2N
+−ℓ
+√
+2N
+ℓ
+√
+2N
+Figure 5. (a) The density (54) for N = 100 electrons and a ‘flower’ edge deformation (24) of order k = 3. The constancy of
+density in the bulk and its sharp decay at the boundary are manifest. (b) The current’s norm (58) for the same flower-shaped
+droplet. The localization on the edge equipotential (black line) is clearly visible, as is the position-dependent width of the
+Gaussian jump. (c) The correlation function C(x1, x2) (61) for the same flower-shaped droplet, seen as a function of x2 when
+x1 = (ℓ
+�
+Nλ(0), 0) is fixed close to the edge of the droplet.
+numbers m = 0, 1, . . . , N − 1. Then the correlation func-
+tion between the points x1 and x2 is
+C(x1, x2) =
+N−1
+�
+m=0
+ψ∗
+m(x1) ψm(x2),
+(59)
+which reduces to the density (50) when x1 = x2.
+As
+before, we rename m ≡ N − k and let the complex coor-
+dinates z, w corresponding to x1, x2 be such that
+z =
+�√
+N + a
+��
+f ′(ϕ1) eiϕ1,
+w =
+�√
+N + b
+��
+f ′(ϕ2) eiϕ2,
+(60)
+where a, b are finite at large N and ϕ1, ϕ2 are the po-
+lar angles of x1, x2.
+One can then plug the Gaussian
+wave functions (41) into (59), this time assuming k fi-
+nite, and performing the sum over k. The gradient ex-
+pansion of the potential implies that the ratio Γm/Ωm ∼
+ΓN/ΩN + O(ℓ2) is nearly constant in this regime, so Eq.
+(59) becomes a geometric sum over k that reproduces the
+result stated in (16) with λ = 2f ′:
+C(x1, x2) ∼
+eiΘN(x1,x2)
+(2π)3/2ℓ2√
+N
+1
+�
+σ(ϕ1)σ(ϕ2)
+×
+i e
+−
+a2
+σ(ϕ1)2 −
+b2
+σ(ϕ2)2
+2 sin
+�
+[f(ϕ1) − f(ϕ2)]/2
+�,
+(61)
+where σ(ϕ) is the angle-dependent width (42). The over-
+all phase ΘN(x1, x2) = ΘN(x2) − ΘN(x1) is given by
+(44), and involves in particular the WKB phase (34).
+Some features of (61) are worth emphasizing. First,
+note
+the
+Gaussian
+jump
+of
+power-law
+correlations
+near the edge, involving a free fermion correlation ∝
+sin([f(ϕ1)−f(ϕ2)]/2)−1 expressed in terms of f(ϕ1) and
+f(ϕ2); this is the standard static diagnostic of the pres-
+ence of edge modes [10, 59, 76]. A second striking aspect
+is the apparent lack of translation-invariance along the
+edge, caused not only by the argument f(ϕ1) − f(ϕ2) =
+� ϕ1
+ϕ2 dθ f ′(θ) but also by the widths σ(ϕ1) and σ(ϕ2). In
+particular, the product σ(ϕ1)−1/2σ(ϕ2)−1/2 is reminis-
+cent of prefactors picked up by primary fields in CFT
+under conformal maps.
+Since the boundary correlator (61) holds in any edge-
+deformed trap (25), it also applies to special cases of in-
+terest such as the anisotropic harmonic potential (47).
+The corresponding correlations were actually computed
+long ago in [68], and they coincide with our result (61)
+upon using the map (24) with k = 2, α = cosh λ,
+β = sinh λ. In fact, this specific setup is also well known
+in the context of the Coulomb gas, since edge correla-
+tions can then be related by a conformal map to the
+standard Euclidean correlation function (z1 − z2)−1 of a
+free fermion CFT [77].
+Finally,
+it is a simple matter to include time-
+dependence in the correlator (61). Indeed, the occupied
+one-particle states in (59) have definite energies Em given
+by (37) at large m. This spectrum is approximately linear
+close to the Fermi energy: changing variables according
+to m = N + k with k finite at large N, one has
+EN+k − EN ∼ ℏω k
+(62)
+where ω ≡ ℓ2ΩN/ℏ is the angular Fermi velocity given
+by the derivative (33) at m = N.
+Note that ω re-
+ceives a number of subleading quantum corrections in-
+volving e.g. the curvature ΓN in (33) [78–80]; we ne-
+glect those.
+In the linear regime (62), one can repeat
+the asymptotic computation of the correlator and find
+
+-
+1
+1
+1
+1
+-
+4
+r
+-
+1
+1
+1
+1
+1
+1
+-
+1
+-
+1
+1
+-
+1
+1
+1
+113
+once more a result of the form (61), now with a time-
+dependent overall phase and a time-dependent denom-
+inator 2 sin
+�
+[f(ϕ1) − f(ϕ2) − ω(t1 − t2)]/2
+�
+.
+This ex-
+hibits the standard ballistic propagation of correlations
+in a CFT, which we confirm below by deriving the effec-
+tive low-energy dynamics of our droplet.
+D.
+Edge modes
+The effective low-energy description of anisotropic QH
+droplets can be derived similarly to the isotropic case
+[59] inspired by Luttinger-liquid theory [81].
+This has
+the advantage of circumventing topological field theory,
+at the cost of failing to apply in fractional QH states [6–
+10]. We now provide such a first-principles calculation,
+eventually concluding that edge modes span a free chiral
+CFT expressed in terms of the angle coordinate f(ϕ)
+along the boundary.
+Aside from its intrinsic interest,
+this computation provides an independent check of the
+validity of the correlation (61).
+Our starting point is the second-quantized Hamilto-
+nian in a Fock space of free fermions,
+H =
+�
+m,n
+(Em,n − µ)a†
+m,nam,n.
+(63)
+Here the sum runs over eigenstates of the one-body
+Hamiltonian (1), labeled by the Landau level n ∈ N
+and the ‘action variable’ quantum number m ∈ N within
+each level. Their energies are denoted Em,n, and µ is
+some chemical potential to be fixed below.
+For each
+pair (m, n), the operator a†
+m,n creates the corresponding
+eigenstate. The exact energy spectrum is unknown, but
+this is not an issue since low-energy excitations all be-
+long to the LLL, with an approximately linear dispersion
+(62) within a window [−Λ, Λ] around the Fermi momen-
+tum. Then choosing the chemical potential of (63) as
+µ = const − 1
+2ℏω, the low-energy approximation of the
+many-body Hamiltonian (63) becomes
+H ∼
+�
+k∈[−Λ,Λ]
+ℏω (k + 1/2) a†
+N+kaN+k,
+(64)
+where the sum is over all integers k in the specified win-
+dow. Since aN+k are fermionic Fock space operators, the
+Λ → ∞ limit of (64) yields a gapless Hamiltonian for free
+fermions written in Fourier modes, and the chemical po-
+tential enforces antiperiodic (Neveu-Schwarz) boundary
+conditions. It now only remains to relate the edge CFT
+to bulk wave functions.
+To this end, note that the Fock space operators in (64)
+create states in the LLL that are given by the Gaussian
+wave function (41). One can therefore express them in
+terms of 2D creation operators c†(x):
+a†
+N+k ∼
+� f ′(ϕ) dϕ
+√
+2π
+ei(k+1/2)f(ϕ) Ψ†(f(ϕ)),
+(65)
+where the 1D fermionic field Ψ is defined as a radial in-
+tegral involving the wave function (41),
+Ψ†(f(ϕ)) ≡ ei(N−1/2)f(ϕ) eiΦ(ϕ)
+f ′(ϕ)
+�
+σ(ϕ)
+×
+� ∞
+0
+r dr
+ℓ(2πN)1/4 c†(x) e
+−
+1
+σ2(ϕ)
+�
+r
+√
+2ℓ2f′(ϕ) −
+√
+N
+�2
+(66)
+with σ the width (42) and Φ the WKB phase (34). Note
+that in writing (66) we assumed that the momentum in-
+dex k and the cutoff Λ are of order O(1) in the thermo-
+dynamic limit. It is then clear that the operator Ψ†(ϕ)
+creates an electron at the position ϕ on the edge.
+From this point onward, the derivation of the low-
+energy effective field theory is essentially done. Indeed,
+the Hamiltonian (64) expressed in terms of the edge field
+(66) reads
+H = ℏω
+�
+dθ Ψ†(θ) (−i∂θ)Ψ(θ).
+(67)
+Furthermore, the normalization of the field Ψ defined by
+(66) is canonical in angle variables: using the standard
+anticommutator {c(x1), c†(x2)} = δ(2)(x1 −x2), one sim-
+ilarly finds {Ψ(f(ϕ1)), Ψ†(f(ϕ2))} = δ(f(ϕ1) − f(ϕ2)) in
+terms of the Dirac delta function on a circle. This de-
+termines the kinetic term of the action functional for Ψ,
+which is thus a canonical fermionic expression ∼ Ψ†∂tΨ.
+It can be combined with the Hamiltonian (64) to write
+down the fermionic action functional of edge modes,
+S[Ψ, Ψ†] = ℏ
+�
+dt dθ iΨ†(θ)
+�
+∂t + ω∂θ
+�
+Ψ(θ),
+(68)
+where we recall that the angular Fermi velocity is ω =
+ℓ2ΩN/ℏ, given by (33). This is manifestly a (1+1)D free
+chiral CFT in terms of the angle variable θ = f(ϕ).
+The low-energy effective theory (68) is universal: for
+any trapping potential, edge modes are described by a
+chiral fermionic CFT expressed in terms of the angle co-
+ordinate of the trap at the boundary, as could have been
+guessed from the dynamics of electronic guiding centers
+induced by the potential V in the non-commutative plane
+(6). In the present case, the angle coordinate was just
+θ = f(ϕ); more general cases involve more complicated
+action-angle variables. We stress that the angle variable
+generally has nothing to do with other obvious position
+coordinates, such as the polar angle ϕ or the arc length
+s(ϕ) = ℓ
+√
+2N
+� ϕ
+0
+dα
+�
+f ′(α) + f ′′(α)2
+4f ′(α) .
+(69)
+Any such ‘wrong’ coordinate makes the apparent Fermi
+velocity of edge modes position-dependent. This is rem-
+iniscent of inhomogeneous CFTs whose light-cones are
+curved owing to the presence of a non-zero space-time
+curvature [82–89].
+However, one should keep in mind
+that our edge modes sense a flat metric ω2dt2 − dθ2 =
+
+14
+ω2dt2 − f ′(ϕ)2dϕ2 whose light-cones are straight lines in
+terms of the angle variable θ = f(ϕ).
+Let us conclude this section by showing that the action
+(68) is consistent with the seemingly complicated corre-
+lator (61). We start from the definition (66) to write the
+1D correlation function ⟨Ψ†(θ1)Ψ(θ2)⟩ as a double radial
+integral of the 2D quantity ⟨c†(x1)c(x2)⟩. Now using the
+asymptotic relation (61), one finds that all normaliza-
+tions simplify and the correlator of the edge field boils
+down to
+⟨Ψ†(θ1)Ψ(θ2)⟩ = 1
+2π
+i
+2 sin
+�
+[θ1 − θ2]/2
+�.
+(70)
+The same result would have been obtained directly from
+the low-energy action (68): it is a correlation function
+of free gapless fermions written in terms of the angle
+coordinates θ1 = f(ϕ1) and θ2 = f(ϕ2). As a bonus,
+time-dependent correlations automatically satisfy the be-
+haviour ∝ sin
+�
+[θ1 − θ2 − ω(t1 − t2)]/2
+�−1 stated at the
+end of Sec. V C.
+VI.
+CONCLUSION AND OUTLOOK
+This work was devoted to a detailed study of meso-
+scopic droplets of non-interacting planar electrons placed
+in a perpendicular magnetic field and confined by star-
+shaped anisotropic traps with scale-invariant level curves.
+In particular, we provided explicit formulas for the corre-
+sponding wave functions and energy spectrum, allowing
+us to compute the many-body density, current, and cor-
+relations of an entire droplet. The resulting low-energy
+edge modes were eventually shown to behave as a chiral
+CFT in terms of the angle variable along the boundary.
+This was all achieved in a regime of high magnetic fields,
+ultimately equivalent to a semiclassical limit.
+These results pave the way for a number of applications
+and follow-ups. Indeed, recent advances in quantum sim-
+ulation suggest the tantalizing possibility of probing lo-
+cal properties of QH-like droplets in the lab [21–24], both
+for static ground states and their dynamical edge excita-
+tions. The density (54) or the current (57) then predict
+observable shape-dependent widths, while the low-energy
+theory (68) predicts the ballistic propagation of local
+boundary disturbances with a position-dependent veloc-
+ity. More generally, the geometry of the QH effect [33–
+39] could soon become relevant for experiments involv-
+ing ultracold atoms or photonics. Our framework pro-
+vides a bridge between this field of mathematical physics
+and concrete observables in mesoscopic quantum physics.
+Verifying the predictions put forward here, through lin-
+ear response experiments or direct imaging, would be a
+fascinating example of many-body quantum mechanics
+at work.
+Turning now to theory, the link between our formal-
+ism and QH symmetries deserves further study: following
+the series of works [58–63], one can think of edge defor-
+mations as approximately unitary operators acting on
+many-body QH states. It is then natural to wonder how
+these operators get composed together; do they span a
+Virasoro group as in CFT? If yes, how to derive the cen-
+tral charge c = 1 in terms of microscopic wave functions?
+More broadly, what are the operators implementing area-
+preserving deformations in the sense of the WKB ansatz
+(20)? One expects these operators to provide a finite (ex-
+ponentiated) form of the operators studied in [58, 60, 61],
+with non-commutative composition laws consistent with
+the geometry (6) of LLL physics.
+Note that the discussion above was mostly focused on
+leading-order properties. For instance, one may wonder
+what are irrelevant corrections to the edge field theory
+(68), especially following the recent numerical observa-
+tion [79] that density waves on the edge satisfy a non-
+linear Korteweg-de Vries equation at late times.
+This
+regime is presumably described by small droplet defor-
+mations of the form r2 �→ r2 + α(ϕ), spanning a U(1)
+Kac-Moody algebra whose level is sensitive to the fill-
+ing fraction [58, 60, 61]. The resulting non-linear edge
+waves would then be described by an evolution equa-
+tion in an infinite-dimensional group manifold. This per-
+spective is standard in hydrodynamics [90–92], but it
+has only recently come to be appreciated in condensed
+matter physics [93]. The geometric study initiated here
+provides a basis for considerations of this kind in the
+QH effect, including the possibility of inhomogeneous
+(position-dependent) corrections in anisotropic traps.
+Another obvious extension of this work is the fractional
+QH regime. In that context, no single-particle descrip-
+tion is available, but many-body predictions such as the
+edge density (54) or the current (57) conceivably display
+universal geometric features that would remain true in
+interacting many-body ground states [42]. It would be
+thrilling to derive such predictions from the family of
+edge transformations studied here, either from a micro-
+scopic analysis of the Laughlin wave function, or thanks
+to the reformulation of fractional QH states as CFT cor-
+relation functions [94].
+ACKNOWLEDGMENTS
+We are grateful to Laurent Charles for illuminating
+discussions on semiclassical methods in Kählerian geo-
+metric quantization. B.O. also thanks Mathieu Beauvil-
+lain, Nathan Goldman, and Marios Petropoulos for col-
+laboration on closely related subjects.
+Finally, we ac-
+knowledge useful and motivating interactions with Jean
+Dalibard, Benoit Douçot, Jean-Noël Fuchs, Marc Geiller,
+Gian Michele Graf, Semyon Klevtsov, Titus Neupert
+and Nicolas Regnault. The work of B.O. is supported
+by the European Union’s Horizon 2020 research and in-
+novation programme under the Marie Skłodowska-Curie
+grant agreement No. 846244. B.L. acknowledges fund-
+ing from the European Research Council (ERC) under
+the European Union’s Horizon 2020 research and inno-
+vation program (Grant No. ERC-StG-Neupert-757867-
+
+15
+PARATOP). P.M. gratefully acknowledges financial sup-
+port from the Wenner-Gren Foundations (No. WGF2019-
+0061). B.E. is supported by the ANR grant TopO No.
+ANR-17-CE30-0013-01.
+Appendix A: Isotropic droplets
+Most of this work is concerned with anisotropic prop-
+erties, so isotropic results provide a useful benchmark.
+They are simpler than their anisotropic counterparts and
+mostly well-known in the literature, so their properties
+are concisely summarized here. We begin by recalling el-
+ementary aspects of the one-body energy spectrum based
+on the exact wave functions (3), then turn to many-body
+observables.
+1.
+One-body spectrum
+Consider a spin-polarized 2D electron governed by the
+Landau Hamiltonian (1) with an isotropic confining po-
+tential V (x) = V0(r2/2). At very strong magnetic fields,
+the resulting one-body spectrum is well approximated
+by the solution of the LLL-projected eigenvalue equa-
+tion (7). As the potential is isotropic, it commutes with
+angular momentum, so the eigenstates of P V P are wave
+functions (3) with definite angular momentum. Note that
+these confirm the general near-Gaussian behavior found
+in (43): letting |z| = √m+a with finite a, one finds that
+(3) behaves at large m as
+φm(x) =
+eimϕ
+√
+2πℓ2
+1
+(2πm)1/4 e−a2 �
+1 + O(1/√m)
+�
+. (A1)
+The energy Em of each state (3) is readily found by com-
+puting the wave function ⟨z, ¯z|PV0(r2/2)P|φm⟩, which
+yields the exact eigenvalue
+Em = ⟨φm|V |φm⟩ = 1
+m!
+� ∞
+0
+dt tm e−t V0(ℓ2t)
+(A2)
+in terms of the integration variable t ≡ |z|2. Note in pass-
+ing that this is the value one would find from first-order
+perturbation theory of the full Landau Hamiltonian (1):
+by construction, LLL-projected physics is only sensitive
+to first-order effects of the potential, while higher-orders
+ultimately involve higher Landau levels.
+Now fix an index m ≥ 0. What is the corresponding
+equipotential in the sense of (9)? To answer this in the
+classical limit, we let m → ∞ while fixing the value of
+ℓ2m = O(1), and evaluate the integral (A2) thanks to a
+saddle-point approximation. The result is
+Em = V0(ℓ2m) + ℓ2Ωm + ℓ2
+2 Γm + O(ℓ4),
+(A3)
+where Ωm and Γm were defined in (33). This is consistent
+with Eqs. (13) and (36) with λ = 2f ′ = 2.
+2.
+Many-body aspects
+The sequence followed here is the same as in Sec. V: we
+start with the density, then consider the current and cor-
+relations close to the edge. In all cases, the edge asymp-
+totics reproduce the formulas of Sec. V for the simplest
+case where f ′(ϕ) = 1.
+Density. Let N ≫ 1 non-interacting planar electrons
+be subjected to the Hamiltonian (1), with a very strong
+magnetic field B = dA and a weak isotropic poten-
+tial V (x) = V0(r2/2).
+The ground state wave func-
+tion of this many-body system is a Slater determinant of
+the occupied single-particle eigenstates φ0, φ1, . . . , φN−1
+given by (3), each of which has a one-body density
+|φm(x)|2. The resulting many-body density is thus (50),
+which can be computed in closed form in the very spe-
+cial case of states (3) with definite angular momentum:
+it is a normalized incomplete gamma function ρ(x) =
+(2πℓ2)−1Γ(N, |z|2)/Γ(N).
+Constancy of density in the
+bulk is then manifest, as is its drop to zero close to
+the edge |z| =
+√
+N, with an error function behavior
+that can be deduced from known asymptotic formulas
+for gamma functions [76] and reproduces Eqs. (14)–(54)
+with λ = 2f ′ = 2.
+Current. For the LLL states (3) with definite angular
+momentum, each one-body current (55) is purely angu-
+lar, i.e. it reads jm = (. . .)dϕ. The sum (56) can then
+be evaluated in closed form owing to an exact cancella-
+tion between the contribution of the states m and m+ 1,
+eventually leading to a current only due to the (N − 1)th
+wave function. It is then trivial to show that the current
+is localized as a Gaussian close to the edge, since this is
+also true of the underlying single-particle wave function.
+This reproduces Eqs. (15)–(57) with λ = 2f ′ = 2.
+Correlations.
+The computation of electronic correla-
+tions close to the edge is similar to that of the density.
+Indeed, since the many-body ground state wave function
+is a Slater determinant, the two-point correlation func-
+tion in the ground state can be expressed as in (59). The
+exact wave functions (3) can then be used to write the
+correlation (59) as an incomplete gamma function (this
+time with a complex argument):
+C(z, ¯z, w, ¯w) =
+1
+2πℓ2
+Γ(N, ¯zw)
+Γ(N)
+e−(|z|2+|w|2)/2 ez ¯
+w. (A4)
+It is then manifest that bulk correlations coincide with
+the kernel (5) at leading order in the thermodynamic
+limit. As for the edge behavior, it can be extracted e.g.
+from a steepest descent argument [76] and reproduces
+Eqs. (16)–(61) with λ = 2f ′ = 2.
+Appendix B: Semiclassical expansion of P V P
+In this appendix, we derive (22) starting from (21).
+To this end, think of V (x, y) as some smooth function of
+
+16
+(x, y) whose arguments can be complexified, and change
+the integration variables (x, y) of (21) to
+s ≡ x −
+ℓ
+√
+2(z + ¯w),
+t ≡ y +
+iℓ
+√
+2(z − ¯w).
+(B1)
+In terms of (s, t), the integrals in (21) are two line in-
+tegrals in the complex plane, each along a path from
+−∞ + ic to +∞ + ic, where c is some irrelevant real con-
+stant (a different one for s and t). The advantage of the
+change of variables (B1) is to make the exponential factor
+in (21) purely Gaussian:
+⟨z, ¯z|P V (x)P|w, ¯w⟩ =
+1
+(2πℓ2)2 e− |z−w|2
+2
+e
+z ¯
+w−¯zw
+2
+×
+�
+ds dt V
+�
+s+ ℓ
+√
+2(z + ¯w), t− iℓ
+√
+2(z − ¯w)
+�
+e− s2+t2
+2ℓ2 .
+(B2)
+We then complexify V , thus replacing V (x, y) by V(z, ¯z),
+where V(z, ¯w) is a function of two complex variables,
+holomorphic in the first one and anti-holomorphic in the
+second.
+We can then deform independently both inte-
+gration contours for s and t back to the real line. For
+small ℓ, the Gaussian factor of (B2) localizes everything
+to s = t = 0. We now use our assumption of slow varia-
+tion of V (x) to Taylor-expand it as
+V
+�
+s +
+ℓ
+√
+2(z + ¯w), t −
+iℓ
+√
+2(z − ¯w)
+�
+∼
+�
+V + s2
+2 ∂2
+xV + t2
+2 ∂2
+yV
+����� ℓ
+√
+2 (z+ ¯
+w),− iℓ
+√
+2 (z− ¯
+w)
+�,
+(B3)
+where we only kept terms that give non-zero contribu-
+tions to the O(ℓ2) approximation of the integral (B2).
+Note that everything is evaluated at (x, y) = ( ℓ
+√
+2(z +
+¯w), − iℓ
+√
+2(z − ¯w)); in complex coordinates, this is just
+the point (z, ¯w), so it is simpler to write the potential
+as V(z, ¯w). Plugging the expansion (B3) into (B2) then
+yields the result (22).
+Appendix C: The transport equation
+The purpose of this appendix is to derive the real and
+imaginary parts of the transport equation in (32) and
+(38), respectively, by imposing the eigenvalue equation
+(7) based on our WKB ansatz (30) in the case of edge-
+deformed droplets. The derivation relies on expanding
+the energy and the potential as in (9) and (22).
+It is
+divided in two parts. First, we use the eigenvalue equa-
+tion to derive the constraint (31), and let z belong to an
+equipotential so that the whole equation boils down to
+a 1D integral identity. Second, we show that the inte-
+gral has a sharp saddle point in the large m limit; this
+allows us to rephrase the integral constraint as a first-
+order transport equation for the unknown function n.
+1.
+Evaluation along an equipotential
+Using the wave functions (18)–(19) and the expansion
+(22) of the potential along with the projector property
+P 2 = P, the eigenvalue problem (7) reads
+0 =
+�
+R2
+d2w
+2πℓ2 e− |z−w|2
+2
++ z ¯
+w−¯zw
+2
+��
+V+ ℓ2
+2 ∇2V
+����
+(z, ¯
+w)−Em
+�
+×
+�
+dθ n(θ) eimθ δ2�
+w −
+�
+F(m, θ), G(m, θ)
+��
+(C1)
+up to O(ℓ4) corrections [95]. In the case of edge-deformed
+traps, V(z, ¯w) is the bicomplex potential given in (28)
+and the delta function localizes the whole integral over
+w to a level curve (27) with K = m. Integrating over w
+and changing the integration variable from θ = f(ϕ) to
+ϕ yields Eq. (31).
+Note that the structure of Eqs. (C1) and (31) is 0 =
+e−|z|2/2 F(z) for a holomorphic function F(z), so setting
+F(z) = 0 on a closed curve implies F(z) = 0 everywhere.
+Accordingly, we will solve (C1)–(31) along the equipo-
+tential (26) by fixing K = m and parametrizing
+z =
+�
+mf ′(α) eiα,
+α ∈ [0, 2π).
+(C2)
+This ensures that all three terms in the exponent of (31)
+are of the same order O(m). Then (31) with the choice
+(C2) and ϕ ≡ α + ε becomes
+0 =
+� π
+−π
+dε f ′(α + ε) n(f(α + ε)) exp
+�
+imf(α + ε) − 1
+2mf ′(α + ε) + m
+�
+f ′(α)f ′(α + ε) e−iε�
+×
+�
+V
+��
+mf ′(α) eiα,
+�
+mf ′(α + ε) e−i(α+ε)�
++ ℓ2
+2 ∇2V − E0
+m − ℓ2E1
+m
+�
+.
+(C3)
+This rewriting will allow us to carry out the integral thanks to the saddle-point approximation, obtained by expanding
+all terms in powers of ε and leading to a differential equation for n(θ).
+
+17
+2.
+Saddle point and transport equation
+The saddle-point expansion of the integral (C3) is cumbersome but straightforward. The strategy is to expand all
+factors in the integrand up to a suitable power of ε, then perform the resulting integrals of the form
+�
+dε ε# e−Cε2,
+where C is some f-dependent coefficient [see e.g. (C5)]. The powers of ε involved are typically small, as higher powers
+are suppressed in the classical limit [large m and ℓ2m = O(1)]. The fact that the argument of n(θ) also involves a
+factor ε eventually converts the integral into a transport equation of the form n′(θ) ∝ n(θ) [see (C16)].
+We start with (C3) and first expand the exponential, then the potential with its Laplacian, and finally the simplest
+f ′(ϕ)n(f(ϕ)) prefactor. For convenience, we introduce the notation
+A ≡ f ′′
+f ′ ,
+B ≡ f ′′′
+f ′
+(C4)
+for combinations of derivatives of f that often appear below; from now on, expressions of the form f or f ′, etc., are
+all implicitly evaluated at α unless specified otherwise (so f ≡ f(α), f ′ ≡ f ′(α), etc.). Note for future reference the
+useful relation A′ = B − A2.
+The exponential. Using the notation (C4), one has
+exp
+�
+imf(α + ε) − 1
+2mf ′(α + ε) + m
+�
+f ′(α)f ′(α + ε) e−iε�
+∼ eimf+ 1
+2 mf ′ exp
+�
+− 1
+2mf ′ �
+1 + A2
+4
+�
+ε2� �
+1 + mf ′ε3 �
+i
+6 − A
+4 − iB
+12 + iA2
+8 − AB
+8 + A3
+16
+��
+(C5)
+where the factor exp
+�
+imf + mf ′/2
+�
+is ultimately irrelevant for the eigenvalue equation (C3), so we will not include
+it in what follows. The main point of (C5) is to exhibit the leading Gaussian behavior exp
+�
+−(mf ′/2)(1 + A2/4)ε2�
+of the integrand, which will eventually allow us to convert (C3) into a differential equation for the unknown function
+n(θ). In fact, the same exponential term appears in the approximately Gaussian wave function (43).
+The potential. We now turn to the expansions of the potential and of its Laplacian. As a first step, our task is to
+expand the potential
+V
+��
+mf ′ eiα,
+�
+mf ′(α + ε) e−i(α+ε)�
+= V0
+�
+�
+�ℓ2m
+√f ′ �
+f ′(α + ε) e−iε
+f ′
+�
+1
+2i log
+� √f ′ e2iα+iε
+√
+f ′(α+ε)
+��
+�
+�
+�
+∼ V0
+�
+ℓ2m
+�
+1 − iε
+�
+1 + A2
+4
+�
++ ε2 �
+− 1
+2 + B
+8 − 3A2
+8
+− A3
+4i − A4
+16 + AB
+4i + A2B
+32
+� ��
+∼ V0
+�
+ℓ2m
+�
+− iℓ2m ε
+�
+1 + A2
+4
+�
+V ′
+0
+�
+ℓ2m
+�
+− 1
+2ℓ4m2ε2 �
+1 + A2
+4
+�2
+V ′′
+0
+�
+ℓ2m
+�
++ ℓ2m ε2 �
+− 1
+2 + B
+8 − 3A2
+8
+− A3
+4i − A4
+16 + AB
+4i + A2B
+32
+�
+V ′
+0
+�
+ℓ2m
+�
+,
+(C6)
+where we used (28) and then the notation (C4). Aside
+from the contribution of the Laplacian, these are all the
+terms of the potential needed in the eigenvalue equation
+(C3) along an equipotential. As expected, they all ul-
+timately involve the potential and its derivatives at the
+equipotential (26). For ε = 0, the whole expression boils
+down to V0(ℓ2m) alone.
+Let us now turn to the Laplacian term.
+The
+eigenvalue
+equation
+(C3)
+requires
+the
+Laplacian
+evaluated
+at
+the
+complexified
+point
+(z, ¯w)
+=
+��
+mf ′(α) eiα,
+�
+mf ′(α + ε) e−i(α+ε)�
+.
+In
+practice,
+the Laplacian term is multiplied by ℓ2 in (C3), so we
+may safely set ε = 0 when computing it; this removes
+the complexification and allows us to write the Laplacian
+contribution in (C3) as
+ℓ2
+2 ∇2V ∼ ℓ2
+f ′
+�
+1 − B
+4 + A2
+2
+�
+V ′
+0(ℓ2m)
++ ℓ4m
+f ′
+�
+1 + A2
+4
+�
+V ′′
+0 (ℓ2m),
+(C7)
+which follows from the general expression (29) evaluated
+on the equipotential (26).
+All together. Let us finally consider the very first factor
+on the right-hand side of (C3), namely
+f ′(α + ε) n(f(α + ε)) ∼ f ′n(f) + ε
+�
+f ′′n(f) + f ′2n′(f)
+�
+(C8)
+where higher powers of ε are negligible at this order. To
+see why they may be neglected, it is helpful to investigate
+
+18
+the general structure of the small ℓ expansion of (C3):
+the exponential term in (C5) has the form
+exp[imf(. . .)] ∼ const × e−mΛε2(1 + mLε3)
+(C9)
+with m ≫ 1 and Λ, L some O(1) coefficients.
+Sim-
+ilarly, the potential expansion (C6) together with the
+Laplacian correction (C7) can schematically be written as
+V0+ ℓ2
+2 ∇2V0 ∼ V0+ℓ2W0+Gε+Hε2, where V0 ≡ V0(ℓ2m)
+while W0, G, H are again some O(1) coefficients. Finally,
+the expansion (C8) of the prefactor roughly has the form
+f ′n e(...) ∼ const × (f ′n + εIn′ + εJn),
+(C10)
+where I, J are O(1) coefficients.
+Putting together the
+schematic expressions (C9)–(C10) and using the fact that
+constant (i.e. ε-independent) contributions are irrelevant,
+the eigenvalue equation (C3) becomes
+0 =
+�
+dε (f ′n + εIn′ + εJn)e−mΛε2(1 + mLε3)
+×
+�
+V0 + ℓ2W0 + Gε + Hε2 − E0
+m − ℓ2E1
+m
+�
+.
+(C11)
+Here the right-hand side is a sum of integrals whose in-
+tegrand has the form εn e−mΛε2. For odd n, each such
+integral vanishes; for even n, it is non-zero and scales as
+m−n/2. This is why only the first order in ε is needed in
+the expansion (C8): higher powers of ε would yield sub-
+leading corrections to (C11), which can be consistently
+taken into account only by expanding the exponential,
+potential and Laplacian terms up to orders in ε higher
+than what we did above. Here we content ourselves with
+the zeroth and first order terms in ℓ2 (i.e. in 1/m). At
+that level of approximation, (C11) yields the zeroth order
+statement
+V0 − E0
+m = 0
+(C12)
+and the first-order result
+f ′n
+�
+Λℓ2m[W0 −E1
+m]+ H
+2 + 3LG
+4Λ
+�
++ G
+2
+�
+In′ +Jn
+�
+= 0,
+(C13)
+where ℓ2m = O(1) as before. Eq. (C12) confirms that the
+eigenvalue equation holds if E0
+m = V0(ℓ2m), i.e. if the en-
+ergy of the eigenstate |ψm⟩ is that of its equipotential at
+leading order [recall (9)]. More important, (C13) yields
+a transport equation for n, whose schematic form is
+GI
+2
+n′
+n +f ′�
+Λℓ2m(W0−E1
+m)+ H
+2 + 3LG
+4Λ
+�
++ GJ
+2 = 0. (C14)
+We now rely on the expansions (C5)–(C8) to write this
+transport equation explicitly: using the notation (33) and
+plugging (C5)–(C8) into (C3) yields the condition
+0 =
+�
+dε e
+− Kf ′
+2
+�
+1+ A2
+4
+�
+ε2 �
+1 + ε
+�
+A + f ′ n′(f)
+n(f)
+�� �
+1 + Kf ′ε3 �
+i
+6 − A
+4 − iB
+12 + iA2
+8 − AB
+8 + A3
+16
+��
+×
+�
+−iℓ2Kε
+�
+1 + A2
+4
+�
+Ωm − ℓ2Kε2
+2
+�
+1 + A2
+4
+�2
+Γm + ℓ2Kε2 �
+− 1
+2 + B
+8 − 3A2
+8
+− A3
+4i − A4
+16 + AB
+4i + A2B
+32
+�
+Ωm
++ ℓ2
+f ′
+�
+1 − B
+4 + A2
+2
+�
+Ωm + ℓ2
+f ′
+�
+1 + A2
+4
+�
+Γm − ℓ2E1
+m
+�
+,
+(C15)
+whose structure is that announced in (C11), as had to
+be the case. What remains is to multiply all the factors
+in the integrand, keep track of powers of ε and integrate
+over ε, which leads to
+iR′/R =
+�
+1 + A2
+4
+�
+Γm
+2Ωm + 1 − B
+4 + A2
+2 − f ′ E1
+m
+Ωm
+−
+1
+1 + A2
+4
+��
+B
+8 + A4
+16 − A2B
+32
+�
++ i
+�
+A
+4 + 3A3
+16 − AB
+8
+��
+,
+(C16)
+where we introduced R ≡ R(α) ≡ n(f(α)) for simplicity.
+This is the transport equation for the O(1) multiplica-
+tive factor of the WKB ansatz (30). Its real and imag-
+inary parts, respectively, govern the phase and norm of
+n(f(ϕ)) ≡ N(ϕ) eiΦ(ϕ):
+−Φ′ =
+�
+1 + A2
+4
+�
+Γm
+2Ωm − f ′ E1
+m
+Ωm
++
+1
+1+ A2
+4
+�
+1 + 3A2
+4
++ A4
+16 − 3B
+8 − A2B
+32
+�
+, (C17)
+N ′/N = −
+1
+1 + A2
+4
+�
+A
+4 + 3A3
+16 − AB
+8
+�
+.
+(C18)
+The identity B = A′+A2 then reduces these two relations
+to Eqs. (32) and (38) in the main text.
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+4
+− i f′′(α)
+2f′(α)
+�
+1 − i f′′(α)
+2f′(α)
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+�−3
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+r−1∂ϕ + (f ′′/2f ′)∂r
+�
+for |r| = ℓ√2Nf ′. We
+recall that dϕ · ∂ϕ = 1 = dr · ∂r and dϕ · ∂r = 0 = dϕ · ∂r
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+P V P operator to order O(ℓ2), but we just write it as
+zero for simplicity.
+
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new file mode 100644
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+page_content='Anisotropic Quantum Hall Droplets  Blagoje Oblak,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 Bastien Lapierre,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2 Per Moosavi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='3 Jean-Marie Stéphan,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4 and Benoit Estienne5  1CPHT,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' CNRS,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' École Polytechnique,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IP Paris,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' F-91128 Palaiseau,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' France  2Department of Physics,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' University of Zürich,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Winterthurerstrasse 190,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 8057 Zürich,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Switzerland  3Institute for Theoretical Physics,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' ETH Zurich,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Wolfgang-Pauli-Strasse 27,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 8093 Zürich,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Switzerland  4Univ Lyon,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' CNRS,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Université Claude Bernard Lyon 1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Institut Camille Jordan,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' UMR5208,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content=' France  5Sorbonne Université,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' CNRS,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Laboratoire de Physique Théorique et Hautes Energies,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' LPTHE,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' F-75005 Paris,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' France  (Dated: January 4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 2023)  We study two-dimensional (2D) anisotropic droplets of non-interacting electrons in the lowest  Landau level,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' confined by trapping potentials whose level curves have an arbitrary shape at large  distances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Using semiclassical methods, we show that energy eigenstates are localized on equipoten-  tials of the trap, with angle-dependent local widths and heights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We exploit this one-particle insight  to deduce explicit formulas for many-body observables in the thermodynamic limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For instance,  the droplet’s density falls off at the boundary with an angle-dependent width inherited from that of  the underlying wave functions, while the many-body current is localized on the edge, to which it is  tangent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Correlations along the edge are long-ranged, in accordance with the system’s low-energy  edge modes which are described by a free chiral conformal field theory in terms of the angle variable  of the trapping potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' These results are likely to be observable in solid-state systems or quantum  simulators of 2D electron gases with a high degree of control on the confining potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  CONTENTS  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Introduction  1  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Setup and main results  2  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Anisotropic states from area-preserving maps  4  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Edge-deformed anisotropic traps  6  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Many-body observables  10  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Conclusion and outlook  14  Acknowledgments  14  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Isotropic droplets  15  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Semiclassical expansion of P V P  15  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The transport equation  16  References  19  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  INTRODUCTION  Quantum Hall (QH) droplets are mesoscopic two-  dimensional (2D) electron gases placed in a strong per-  pendicular magnetic field and confined by some electro-  static potential: see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' They lie at the heart of the  QH effect [1–3] and provide a key benchmark for topolog-  ical phases of matter as a whole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In practice, however,  the vast majority of detailed analytical studies of QH  droplets are limited to highly symmetric cases, typically  involving isotropic traps or harmonic potentials that are  translation-invariant in one direction [4, 5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is espe-  cially troubling as far as edge properties are concerned,  since these are sensitive to the shape of the trap and  determine the system’s low-energy excitations [6–10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The goal of this paper is to address this lack of analyt-  ical results by predicting universal aspects of many-body  observables near the edge of essentially any anisotropic  droplet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We achieve this by providing general, explicit,  one-line formulas for the density, current, and correla-  tions in the regime of strong magnetic fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We also  study the corresponding low-energy edge modes, which  are described by a free-fermion chiral conformal field the-  ory (CFT) whose Fermi velocity is constant provided dis-  tances along the boundary are measured by the canonical  angle variable determined by the potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' These pre-  dictions are likely to be observable thanks to direct local  imaging techniques in condensed matter systems [11–16]  or quantum simulators [17–24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This is not the first time such questions appear in the  literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, random potentials with no symme-  tries are essential to model disorder, whose importance  for the robustness of QH physics is hard to overstate [25–  27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' An especially relevant series of works in that con-  text is [28, 29], which study the density and current of  QH droplets with arbitrary potentials, at finite temper-  ature, generally including Landau level mixing, in the  semiclassical limit of strong magnetic fields and weak  traps [26, 27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' However, the coherent states used in these  references do not allow for any resolution at the single-  particle level, precluding the computation of low-energy  dynamics and long-range correlations along the bound-  ary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Our objective here is instead to find explicit wave  functions that depend on the shape of the edge, and use  that as a starting point for many-body objects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Regarding electronic edge correlations, similar ques-  tions have been addressed in the context of classical 2D  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='01726v1  [cond-mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='mes-hall]  4 Jan 2023  2  Energy  Fermi  energy  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  2D electron droplet (shaded area) placed in a  strong perpendicular magnetic field and confined by a typical  anisotropic edge-deformed potential well (10).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' At leading or-  der in the thermodynamic limit, the droplet’s boundary (thick  black curve) coincides with the equipotential of the trap at the  Fermi energy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Coulomb gases, where holomorphic methods play a key  role [30–32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' More broadly, the results put forward here  may be seen as microscopic, first-principles derivations  of quantities that are normally studied within less con-  trolled approximation schemes in the geometry of the QH  effect [33–39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Our hope is thus to build a bridge between  these theoretical works and concrete observations that  may soon be accessible in tabletop experiments with a  high degree of control on the confining potential [23, 24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Here is the plan of the paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' To begin, Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' II sum-  marizes our methods and results, avoiding all techni-  cal details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The next two sections are devoted to one-  body physics in the lowest Landau level: Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III first  discusses generalities on semiclassical holomorphic wave  functions, while Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV presents a detailed computation  of the semiclassical energy spectrum in a class of ‘edge-  deformed’ potentials of particular interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This finally  leads to Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' V, where we investigate many-body densi-  ties, currents, correlations, and low-energy edge modes in  anisotropic traps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We conclude in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' VI by discussing  several follow-ups and open questions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' To streamline the  text, non-essential details are deferred to Apps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' A–C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  SETUP AND MAIN RESULTS  This section summarizes our methods and key results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  To start, we describe the general setup: a semiclassi-  cal limit (strong magnetic field, small magnetic length)  in the lowest Landau level (LLL) [26, 27, 40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We then  introduce edge-deformed potentials and present their ap-  proximate energy eigenstates, before finally giving simple  formulas for the corresponding local many-body observ-  ables and dynamics in the vicinity of the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Some of  these findings are depicted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Semi-classical limit in the LLL  This work concerns spin-polarized non-interacting elec-  trons of mass M and charge q in a 2D plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Each  electron is governed by a Landau Hamiltonian with an  anisotropic potential V (x),  H1-body =  1  2M (p − qA)2 + V (x),  (1)  where A is the vector potential of the magnetic field  B = dA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (We view A as a one-form, which simplifies  some notation but is otherwise inconsequential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=') We shall  assume that V (x) is ‘monotonous’, by which we mean  that it has a unique global minimum away from which it  grows monotonously, but it is otherwise general.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Conse-  quently, the level curves or ‘equipotentials’ of V (x) are  nested and take the form shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 2(a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We assume  throughout that the potential is weak relative to the mag-  netic field [26–29, 41, 42], and that it is nearly constant  on length scales comparable to the magnetic length  ℓ2 ≡ ℏ  qB > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (2)  In that regime, the potential is a small perturbation of  the pure Landau Hamiltonian ∝ (p−qA)2 and the eigen-  states of (1) are expected to be well-approximated by  wave functions in the LLL.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For instance, if the potential  V (x) = V0(r2/2) is isotropic, the eigenstates of (1) have  some definite angular momentum and reduce at strong  B to standard LLL wave functions in symmetric gauge:  φm(x) =  1  √  2πℓ2  zm  √  m!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  e−|z|2/2,  (3)  where m ≥ 0 is an integer angular momentum and we  have introduced the dimensionless complex coordinate  z ≡ x + iy  √  2ℓ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (4)  Each wave function (3) reaches its maximum on the cir-  cle |z| = √m, away from which it decays in a Gaussian  manner within a magnetic length.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Our goal will be to ob-  tain similar approximate eigenstates in anisotropic traps,  using the squared magnetic length (2) as a small expan-  sion parameter [43].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Equivalently, we shall carry out a  semiclassical (small ℏ), high field expansion (large B).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In practice, the projection to the LLL is implemented  thanks to the (one-body) operator P ≡ �∞  m=0 |φm⟩⟨φm|,  whose kernel can be read off from the wave functions (3):  ⟨z, ¯z|P|w, ¯w⟩ =  1  2πℓ2 e−(|z|2+|w|2)/2 ez ¯  w.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (5)  This is manifestly Gaussian and reduces to a delta func-  tion in the formal semiclassical limit ℓ → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' At small but  finite ℓ, the projection (5) makes space non-commutative  in the sense that the LLL-projected position operators  (x, y) satisfy the Heisenberg algebra  [PxP, PyP] = iℓ2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (6)  3  ���  ���  ���  x  x  x  y  y  y  √  N  −  √  N  −  √  N  √  N  (a)  (b)  (c)  x  x  x  y  y  y  ℓ  √  2N  −ℓ  √  2N  −ℓ  √  2N  ℓ  √  2N  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (a) A planar plot of the many-body density (14) along with several equipotentials (dashed lines), for a droplet of  N = 100 electrons confined by the edge-deformed trap of Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The constancy of the bulk density and its fall at the boundary  are manifest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (b) The current’s norm (15) for the same droplet, together with the edge (black line) on which it is localized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (c) The correlation function (16) for the same droplet, seen as a function of x2 = (x, y) with x1 = (ℓ  �  Nλ(0), 0) denoted by a  cross and fixed at the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Long-range correlations along the boundary are clearly visible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  One can thus think of the plane R2 as a ‘phase space’  whose canonical variables are x, y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This interpretation  pervades much of the QH literature [40, 44–53] and will  similarly affect our discussion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Indeed, projecting the  Hamiltonian (1) to the LLL and looking for its spectrum  leads to the eigenvalue equation  P V P|ψ⟩ = E|ψ⟩,  (7)  where the unknowns are the energy E and the quantum  state |ψ⟩ ∈ LLL.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note that the kinetic term of (1) has  disappeared in (7): the potential itself plays the role of  an effective Hamiltonian in the non-commutative phase  space (x, y).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Exact solutions of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (7) are generally out of reach,  so one has to resort to approximations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The semiclassical  one that we shall use is well known in the QH context  [26–29, 54, 55].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Accordingly, we will look for solutions of  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (7) labeled by a large quantum number m ∈ N, seen  as a generalization of angular momentum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This large  m limit is accompanied by a small ℓ limit, such that  the area 2πℓ2m remains finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In that regime, the mth  eigenstate is approximately Gaussian and localized on an  equipotential γm of V (x), enclosing a quantized area such  that the Bohr-Sommerfeld condition holds:  �  γm  x dy = 2πℓ2 m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (8)  Equivalently, the flux of the magnetic field through the  area enclosed by γm is m times the flux quantum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The  energy of the mth state is then  Em = E0  m + ℓ2E1  m + O(ℓ4),  (9)  where E0  m = V (γm) is the leading classical approxima-  tion and the quantum correction E1  m involves the Lapla-  cian of the potential and the curvature of the equipo-  tential γm [54, 55].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note that the more familiar Wentzel-  Kramers-Brillouin (WKB) approximation of 1D quantum  mechanics [56] includes (topological) Maslov corrections  on the right-hand side of (8);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' we will find similar correc-  tions below, although their interpretation as topological  invariants is prevented by a subtle distinction between  real and Kählerian polarizations in geometric quantiza-  tion [54, 55].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  One-body results  The semiclassical limit just outlined applies to any  (monotonous) weak potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In practice, our main con-  cern is the physics of QH droplets near the edge, where  the details of the bulk potential are irrelevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Most  of our explicit results will therefore be given for ‘edge-  deformed’ potentials, obtained as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Consider any  monotonously increasing function V0(t) for t ≥ 0, and let  λ(ϕ) be any strictly positive 2π-periodic function of the  angle ϕ ∈ [0, 2π);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' normalize λ so that  �  dϕ λ(ϕ) = 4π,  where we write  �  dϕ as a shorthand for  � 2π  0  dϕ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then  adopt polar coordinates in the plane such that x + iy =  r eiϕ and define the potential  V (r, ϕ) = V0  � r2  λ(ϕ)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (10)  We refer to this as an edge-deformed trap because it re-  sults from a deformation r2 �→ r2/λ(ϕ) that changes the  shape of the boundary of isotropic droplets in a finite  and smooth way, even in the thermodynamic limit where  the droplet’s area goes to infinity [57].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In fact, the cor-  responding infinitesimal transformations are expected to  1  1 1  1 1  1  1  1  1  1  1  1  1  1  1  1  4  be conformal transformations of the edge CFT [58–63].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The class of potentials (10) is thus exhaustive, at least  as far as edge effects are concerned.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The traps (10) turn out to allow for explicit calcula-  tions of the semiclassical energy spectrum, generalizing  the known isotropic results reviewed in App.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed,  we show in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV that the corresponding eigenfunc-  tions, solving (7) in the LLL, are Gaussians localized on  equipotentials r = ℓ  �  mλ(ϕ) at large quantum numbers  m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' They can be written in polar coordinates as  ψm(x) ∼  eiΘm(x)  �  2πℓ2σ(ϕ)  e−a2/σ(ϕ)2  (2πm)1/4 ,  (11)  where Θm(x) is a position-dependent phase, a ≡  �  r −  ℓ  �  mλ(ϕ)  ��  ℓ  �  λ(ϕ) is a dimensionless radial coordinate  that measures the distance from the equipotential, and  σ(ϕ) ≡  �  2  λ(ϕ)  �  1 +  � λ′(ϕ)  2λ(ϕ)  �2  (12)  is an angle-dependent width.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We stress that this exhibits  the expected ‘quantum smearing’ of wave functions in a  strong but finite magnetic field [28, 29], which would be  missed by the leading classical approximations ℓ2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  As for the energy of the state (11), its expansion (9)  up to neglected O(ℓ4) contributions is  Em ∼ V (γm) + ℓ2  2 Ωm  �  1 +  �  1 + Γm  Ωm  � � dϕ  4π λ(ϕ)σ(ϕ)2  �  ,  (13)  where V (γm) = V0  �  ℓ2m  �  is the leading term, while  the first quantum correction involves derivatives Ωm ≡  V ′  0(ℓ2m) > 0 and Γm ≡ ℓ2m V ′′  0 (ℓ2m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Each mth energy  is thus determined by the potential and its derivatives at  an equipotential that satisfies the quantization condition  (8), in accordance with general theorems for holomorphic  WKB theory [54, 55].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Many-body results  Now consider the ground state of a large number  N ≫ 1 of free spin-polarized electrons, each governed by  the single-particle Hamiltonian (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This ground state  is a Slater determinant of wave functions whose large m  behavior is the Gaussian (11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As we show in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' V,  the corresponding many-body density, current, correla-  tions, and low-energy effective action can all be written  in closed form in terms of λ(ϕ) and the number N of  fermions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The density ρ(x) = �N−1  m=0 |ψm(x)|2 thus sat-  isfies the bulk behavior ρ ∼  1  2πℓ2 , while its form near the  edge is given by a complementary error function:  ρ(r, ϕ) ∼  1  4πℓ2 erfc  �√  2 a  σ(ϕ)  �  ,  (14)  where a ≡  �  r − ℓ  �  Nλ(ϕ)  ��  ℓ  �  λ(ϕ) is again a dimen-  sionless radial coordinate, now measuring the distance  from the edge at redge = ℓ  �  Nλ(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  As a result, the  ground state forms a star-shaped droplet whose bound-  ary has an angle-dependent width (12) inherited from  that of one-body wave functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Turning to the current  J = �N−1  m=0  1  2i(ψ∗  mdψm − ψmdψ∗  m − 2iqA|ψm|2), we write  it as a one-form in polar coordinates to find  J(r, ϕ) ∼ −  exp  �  − 2a2  σ(ϕ)2  �  (2πℓ2)3/2σ(ϕ)  �  ℓ  √  N dϕ +  λ′(ϕ)  2λ(ϕ)3/2 dr  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (15)  This is localized on the edge and tangent to it, miss-  ing the bulk behavior Ji ∝ εij∂jV as expected in the  LLL [41, 42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Finally, the two-point correlation function  C(x1, x2) = �N−1  m=0 ψ∗  m(x1)ψm(x2) behaves near the edge  as  C(x1, x2) ∼  eiΘN(x1,x2)  4πℓ2�  σ(ϕ1)σ(ϕ2)  i exp  �  −  a2  σ(ϕ1)2 −  b2  σ(ϕ2)2  �  √  2πN sin  �� ϕ1  ϕ2  dθ  4 λ(θ)  �  (16)  with a ≡  �  |x1| − ℓ  �  Nλ(ϕ1)  ��  ℓ  �  λ(ϕ1) and similarly for  b in polar coordinates (|x1|, ϕ1) and (|x2|, ϕ2), respec-  tively, while ΘN(x1, x2) is a complicated overall phase.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note again the Gaussian localization at the edge, as well  as the long-range correlator ∝ sin(.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=')−1 typical of gapless  fermions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, we eventually confirm that the under-  lying low-energy edge modes are described by a chiral  CFT of free fermions: see the action functional (68) be-  low.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The corresponding Fermi velocity is constant along  the boundary when measured in terms of the angle vari-  able of the potential (10), namely θ(ϕ) ≡  � ϕ  0 dϕ′ λ(ϕ′)/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  ANISOTROPIC STATES FROM  AREA-PRESERVING MAPS  This section presents the WKB ansatz [see (20)] that  forms the basis of all our later considerations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The struc-  ture is ultimately quite simple: given a monotonous po-  tential V (x), we pick one of its equipotentials, γm, with  quantized area (8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We then build a wave function with  winding m, perfectly localized on γm, and finally project  it to the LLL using the operator (5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' General theorems  [54, 55] ensure that LLL-projected eigenstates satisfying  (7) can indeed be built in this way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The detailed applica-  tion of this method to edge-deformed traps (10) is given  in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  A note: what follows relies on the mathematics of area-  preserving diffeomorphisms, which is not reviewed in de-  tail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We refer instead to [57] for an introduction whose  language is similar to that adopted here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For more gen-  eral discussions in the symplectic context, see [64, 65].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Potentials in action-angle variables  Let us be more precise about the geometry of the  setup, remaining at the classical level for now.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We pick  5  a smooth potential V (x) and assume as in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' II that it  is monotonous.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Its unique global minimum is thus sur-  rounded by nested level curves, and one can always find  an area-preserving deformation of the plane that sends  each equipotential on a circle [64].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In other words, one  can find an invertible smooth map F : R2 → R2 with  unit Jacobian such that  V  �  F(x)  �  = V0(r2/2),  (17)  where the trap on the right-hand side is isotropic (it only  depends on r = |x|).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' If F is the identity (or a rotation  around the origin), then V was isotropic to begin with  and its eigenstates satisfying (7) are the standard wave  functions (3) with definite angular momentum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In the  more general case of arbitrary V , Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (17) suggests using  F to map the eigenstates (3) on those corresponding to  our general V (x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The existence of F in (17) is guaranteed by the mono-  tonicity of V , and is equivalent to the existence of glob-  ally well-defined action-angle variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In fact, we can  use this to write F in a more explicit form that will be  useful below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Let therefore (ℓ2K, θ) be action-angle co-  ordinates for the potential V (x) [66], where K ≥ 0 is  dimensionless and θ ∈ [0, 2π) is a genuine angle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' They  are normalized so that ℓ2dK ∧ dθ = dx ∧ dy, which is  to say that their Poisson bracket reads {ℓ2K, θ} = ℓ2 in  terms of the phase space (x, y) with bracket (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then  the map (x, y) �→ (ℓ2K, θ) is an area-preserving diffeo-  morphism in terms of which V (x) = V0(ℓ2K(x)) is in-  variant under rotations of θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' To be specific, write these  coordinates as functions K(x, y) and θ(x, y) and let the  inverse be x = F(K, θ) and y = G(K, θ) for some func-  tions (F, G);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' this inverse is nothing but the deformation  F in (17).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In other words, knowing the action-angle vari-  ables of a potential V allows us to map it on its (unique)  isotropic cousin V0, which in turn can be used to relate  the corresponding anisotropic eigenstates to those in (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  It should be clear that these considerations apply to  any monotonous anisotropic trap, in which case one  generally encounters intricate area-preserving maps with  complicated action-angle variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV, we will  argue that most of these difficulties wash away when  focusing on edge physics, whereupon the only relevant  maps are the ‘edge deformations’ mentioned below Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (10).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For now, we remain general and turn to quantum  considerations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Anisotropic eigenstates  Using the action-angle variables (ℓ2K, θ) for V (x),  one can concretize the statements around Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (8)–(9)  into formulas and eventually obtain anisotropic eigen-  functions that satisfy (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, the Bohr-Sommerfeld  quantization condition (8) implies that the equipotential  γm is the set of points in R2 where K = m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Now consider  the following quantum state, perfectly localized on γm:  |Ψm⟩ ≡ 2πℓ2  �  dθ n(θ) eimθ��F(m, θ), G(m, θ)  �  ,  (18)  where the normalization 2πℓ2 is included for later conve-  nience, the ‘wave function’ ⟨x|F(m, θ), G(m, θ)⟩ = δ2�  x−  F(m, θ)  �  is a delta function, and n(θ) is some complex  periodic function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The latter does not wind upon com-  pleting one turn in the plane along the equipotential,  meaning that all the winding of (18) is encoded in the  phase eimθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We stress that (18) is analogous to the standard WKB  ansatz ψ(x) ∼ eiS0(x)/ℏeiS1(x) in 1D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, the phase  eimθ is the leading classical contribution eiS0/ℏ for m ≫ 1,  corresponding to the ‘geometrical optics’ approximation  of the wave function, while n(θ) is the ‘physical optics’  quantum correction eiS1 that eventually needs to satisfy a  transport equation in order for the Schrödinger equation  to hold [56].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The only difference lies in the interpretation  of areas in the plane as values of an ‘action’, which ul-  timately stems from the non-commutative geometry (6)  of LLL physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note that n(θ) is the only unknown in  (18).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, most of the WKB method below will con-  cern the derivation of a transport equation for n(θ) from  the requirement that (7) be satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Starting from Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (18), it is straightforward to build a  state in the LLL thanks to the projector (5): denoting  ψm(z, ¯z) ≡ ⟨z, ¯z|P|Ψm⟩,  (19)  one finds the wave function  ψm(z, ¯z) = e−|z|2/2  �  dθ n(θ) eimθ  × e−[F (m,θ)2+G(m,θ)2]/4ℓ2 ez[F (m,θ)−iG(m,θ)]/  √  2ℓ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (20)  This is manifestly of the form e−|z|2/2 times a holomor-  phic function that depends on the action variable ℓ2m  and the uniformizing map F of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (17).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It will be our  starting point for the semiclassical solution of the eigen-  value equation (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  As a consistency check, note that (20) simplifies for  isotropic potentials.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In that case, action-angle variables  are just polar coordinates ℓ2K = r2/2 and θ = ϕ, and  the map in (17) is F(x) = x, merely implementing a  change from polar to Cartesian coordinates: F(m, θ) =  ℓ  √  2m cos(θ) and G(m, θ) = ℓ  √  2m sin(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' One can then  verify that (20) with n(θ) = const coincides (up to nor-  malization) with the standard LLL wave function (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Similarly to that case, any projected wave function (20)  reaches its maximum on the equipotential γm and is ap-  proximately Gaussian close to it, as ensured by the kernel  (5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This will be confirmed explicitly in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV for edge  deformations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  6  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Expanding the eigenvalue equation  None of what we wrote so far involves a manifest semi-  classical expansion: it is hidden in the eigenvalue equa-  tion (7) and the function n(θ) in (20), since n(θ) should  be expanded as a power series n(θ) = n0(θ) + ℓ2n1(θ) +  O(ℓ4) (as before, there are no odd powers of ℓ since ℓ2 ∝ ℏ  is really the semiclassical parameter).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  It is therefore  worth anticipating the first few terms of the semiclas-  sical approximation of (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We stress that the expansion  below will eventually be limited to the leading order of  the transport equation, so that only n0(θ) will be calcu-  lated in the end.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In principle, one could of course push  the expansion to higher orders for more detailed results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The semiclassical expansion of the right-hand side of  (7) is clear: it is given by the large m, small ℓ2 expan-  sion of the projected wave function (20), including an  expansion of n(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As for the energy, its expansion was  written in (9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The left-hand side of (7) is more subtle, as  its semiclassical expansion involves that of the operator  P V P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The latter is a ‘Berezin-Toeplitz operator’ [54, 55]  that will play an important role for edge-deformed po-  tentials, so we now explain its expansion in some detail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  First, given Cartesian coordinates (x, y), express the po-  tential in complex coordinates (4) as V (x, y) ≡ V(z, ¯z)  for some function V(z, ¯w) which is holomorphic in its first  argument and anti-holomorphic in the second.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then re-  calling that P is the LLL projector with kernel (5), one  finds  ⟨z, ¯z|P V P|w, ¯w⟩ =  1  2πℓ2 e− 1  2 (|z|2+|w|2)  ×  �  R2 du dv V (u, v) e−|X|2+z ¯  X+ ¯  wX  (21)  with X ≡ (u + iv)/  √  2ℓ similarly to (4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Our task is to  expand the integral on the right-hand side in the semi-  classical limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The key is to assume that the potential  varies slowly on the scale of the magnetic length [26–29],  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' we choose once and for all a smooth potential V (x),  independent of ℓ, and let ℓ be small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In that regime, the  integrals in (21) are approximately Gaussian, which gives  (see App.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' A 2)  ⟨z, ¯z|P V P|w, ¯w⟩  ℓ≪1  ∼  1  2πℓ2 e− |z−w|2  2  e  z ¯  w−¯zw  2  ×  �  V(z, ¯w) + ℓ2  2 (∇2V )(z, ¯w)  �  (22)  where  (∇2V )(z, ¯w)  is  the  bicomplex  function  that  corresponds to the Laplacian of the potential,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (∇2V )(z, ¯w) =  4  2ℓ2 ∂z∂ ¯  wV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is the standard semiclas-  sical expansion of a Berezin-Toeplitz operator [54, 55].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note the general structure: the entire P V P operator  boils down to P itself, with kernel (5), multiplied by a  function that coincides with V at leading order but also  includes quantum corrections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In the ‘zoomed-out’ limit  where the kernel of P is a delta function, the first term of  (22) becomes V(z, ¯z)δ2(z − w, ¯z − ¯w) as expected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' More-  over, for harmonic potentials, the truncated expression  (22) is actually exact since the next term ∇4V and all  subsequent ones vanish.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This agrees with the common  lore that ‘WKB is exact for quadratic Hamiltonians’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  EDGE-DEFORMED ANISOTROPIC TRAPS  Here we apply the WKB ansatz of Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III to poten-  tials (10) with scale-invariant level curves, obtained by  acting with edge deformations [57] on an isotropic trap.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  As we explain below, these are the most general traps  one expects to find close to the edge of star-shaped QH  droplets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The plan is as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  First, we introduce  edge deformations and give a few examples for later ref-  erence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Second, we apply Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (7) to edge-deformed traps  and expand it in the classical limit (large m, small ℓ2  with ℓ2m = O(1) kept fixed).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We keep track of all terms  up to order O(ℓ2), so as to capture the leading part of  the transport equation for the function n(θ) in (18)–(20).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This eventually yields an explicit energy spectrum [see  (37)] along with approximately Gaussian eigenfunctions  [see (43)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Lastly, we conclude with a consistency check  by showing that our wave functions reproduce the asymp-  totic (large m) form of the known LLL-projected spec-  trum for anisotropic harmonic traps [67–71].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Edge deformations  We have seen in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III that area-preserving defor-  mations play a key role for the semiclassical solution of  the eigenvalue equation (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The group of all such de-  formations is obviously huge, so it is essential to identify  the subset of transformations that are likely to be im-  portant for low-energy physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In fact, part of this work  has already been carried out, at least implicitly, in the  seminal series of papers [58–63], which we now use as a  basis for the definition of edge deformations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (A similar  motivation was put forward in [57].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=')  Label points on the plane by their polar coordinates  (r, ϕ), defined as usual by x + iy = r eiϕ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Then, the  boundary of any isotropic QH droplet is located at some  fixed radius redge = O(ℓ  √  N).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' What is the most general  area-preserving deformation that preserves this order of  magnitude?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The answer is readily found by realizing that  the constraint of preserving redge = O(ℓ  √  N) is equiva-  lent, at leading order in 1/N, to the condition that the de-  formation commutes with overall dilations r �→ const×r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The most general deformation satisfying this criterion is  an edge deformation  �r2  2 , ϕ  �  �→  �  r2  2f ′(ϕ), f(ϕ)  �  ,  (23)  where f(ϕ) is an (orientation-preserving) deformation of  the circle, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' any smooth map satisfying f(ϕ + 2π) =  7  f(ϕ) + 2π and f ′(ϕ) > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The angle-dependent rescaling  of r on the right-hand side ensures that the map preserves  area, and reproduces the argument of the potential (10)  with λ = 2f ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note that the set of maps (23) is isomor-  phic to the group of diffeomorphisms of the circle, whose  central extension famously leads to the Virasoro algebra  encountered in CFT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, this motivates the state-  ment in [60, 61] that generators of maps (23) in the QH  effect produce conformal transformations of edge modes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We stress that the subset of transformations (23) orig-  inates from an asymptotic analysis of the relevant or-  ders of magnitude.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' One can undoubtedly consider other  families of deformations, motivated by different consid-  erations, but those are irrelevant for our purposes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For  instance, the transformations r2 �→ r2 + α(ϕ) are crucial  for the effective low-energy description of QH droplets  [6, 10, 61], but they are subleading compared to (23) since  they deform the radius redge = O(ℓ  √  N) by terms of order  O(1/N) instead of O(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Conversely, one might consider  ‘higher-spin transformations’ [58, 60, 61] that change the  radius in a dramatic way such as r2 �→ β(ϕ)r4[1+O(1/r)],  but these stretch QH droplets to an infinite extent in the  thermodynamic limit, which is why we discard them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Let us provide a few examples of edge deformations  for future reference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' First, (23) includes rigid rotations  around the origin given by f(ϕ) = ϕ + const.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' A richer  class is obtained by fixing some positive integer k and  considering all maps of the form  eikf(ϕ) = α eikϕ + β  ¯β eikϕ + ¯α  (24)  where α, β are complex and satisfy |α|2 − |β|2 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For  fixed k, such maps span a group locally isomorphic to  SL(2, R), always containing a subgroup of rigid rotations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We will return to these deformations below, since they  can be seen as Fourier modes for circle diffeomorphisms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In particular, setting α = cosh λ and β = sinh λ for some  real parameter λ turns the map (24) into an analogue of  a Lorentz boost with rapidity λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In terms of the bulk  action (23), any deformation (24) turns a circle into a  ‘flower’ with k petals: see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 5 for k = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For k = 2,  this maps the circle on an ellipse [57], which will be useful  for anisotropic harmonic traps in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Edge-deformed potentials  Given an isotropic potential V0(r2/2), how is it affected  by an edge deformation (23)?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The answer is provided by  the anisotropic trap (10) with λ(ϕ) = 2f ′(ϕ):  V (r, ϕ) ≡ V0  �  r2  2f ′(ϕ)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (25)  In what follows, we exclusively consider this class of po-  tentials and refer to them as ‘edge-deformed traps’, for  the reasons stated above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Having fixed once and for all  some circle deformation f(ϕ), our goal is to solve the cor-  responding eigenvalue equation (7) in the classical limit  of high quantum numbers and small magnetic length.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We begin by listing the key classical data of the prob-  lem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The action-angle variables corresponding to (25) are  (ℓ2K, θ) =  �  r2�  (2f ′(ϕ)), f(ϕ)  �  with an inverse given by  (r2/2, ϕ) =  �  ℓ2K/(f −1)′(θ), f −1(θ)  �  , where f −1 denotes  the 1D inverse of f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Points at constant K are equipoten-  tials, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' level curves of (25), each of which is a set of  points such that  r2  2f ′(ϕ) = ℓ2K  (26)  with constant K ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In Cartesian coordinates, this  is the set of points x =  �  2ℓ2Kf ′(ϕ) cos(ϕ), y  =  �  2ℓ2Kf ′(ϕ) sin(ϕ) for ϕ ∈ [0, 2π].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Equivalently, in  terms of the angle variable θ = f(ϕ) ∈ [0, 2π], the equipo-  tential is  x =  �  2ℓ2K  (f −1)′(θ) cos(f −1(θ)) ≡ F(K, θ),  y =  �  2ℓ2K  (f −1)′(θ) sin(f −1(θ)) ≡ G(K, θ),  (27)  where the notation (F, G) was introduced in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that we will eventually focus on the regime where  K ≫ 1 is very large in such a way that the dimensionful  area 2πℓ2K be an O(1) quantity as ℓ → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Moving just slightly away from the classical regime, we  have seen in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III that the expansion of the operator  P V P involves a bicomplex potential function V(z, ¯w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In  the case of edge-deformed potentials (25), with the con-  ventions used there and above for complex coordinates,  one finds  V(z, ¯w) = V0  �  ℓ2  z ¯w  f ′� 1  2i log[z/ ¯w]  �  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (28)  Note that this only makes sense for z and w close to each  other, otherwise taking z → e2πiz affects the argument  of f ′ on the right-hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' By contrast, when z and w  remain close, taking z → e2πiz also requires w → e2πiw,  and this time the angle  1  2i log[z/ ¯w] is indeed invariant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Finally, the expansion (22) also involves the complexi-  fied Laplacian of the potential, but only its real value will  be relevant at the order studied here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Let us therefore  express the Laplacian of (25) in polar coordinates:  ∇2V = 1  f ′  �  2 − 1  2  f ′′′  f ′ + f ′′2  f ′2  �  V ′  0  �  r2/2f ′�  + r2  f ′2  �  1 + f ′′2  4f ′2  �  V ′′  0  �  r2/2f ′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (29)  Here the prime means differentiation with respect to the  argument, namely ϕ for f(ϕ) and r2/2 for V0(r2/2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We  shall rely on (28) and (29) below, since they directly affect  the eigenvalue equation (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  8  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Eigenvalue equation and energy  Having studied the potential (25), let us turn to the  quantum state meant to solve the eigenvalue equation  (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III B, we begin by building a state (18)  that is perfectly localized on the equipotential, project  to the LLL using the operator (5), and obtain the wave  function (20) that now reads  ψm(z, ¯z) = e−|z|2/2  �  dϕ f ′(ϕ) n(f(ϕ))  × exp  �  imf(ϕ) − 1  2mf ′(ϕ) + z  �  mf ′(ϕ) e−iϕ�  ,  (30)  where we changed variables using θ = f(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It remains to  show that this solves the eigenvalue equation (7) for edge-  deformed traps (25) in the semiclassical regime, provided  the function n(θ) satisfies a suitable transport equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The latter is derived by expanding the energy (9) and  the potential (22) to get  0 =  �  dϕ f ′(ϕ) n(f(ϕ))  × exp  �  imf(ϕ) − 1  2mf ′(ϕ) + z  �  mf ′(ϕ) e−iϕ�  ×  �  V  �  z,  �  mf ′(ϕ) e−iϕ�  + ℓ2  2 ∇2V − E0  m − ℓ2E1  m  �  (31)  where V(z, ¯w) is the bicomplex function (28) and the  equation holds up to neglected O(ℓ4) corrections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  At  leading order in the classical limit, the potential expan-  sion (22) boils down to ⟨z|P V P|w⟩ ∼ V(z, ¯z)δ2(z − w),  so (31) merely states that E0  m = V0(ℓ2m) = V (γm).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The  issue is to find the two remaining unknowns: the function  n(f(ϕ)) and the first-order energy correction E1  m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  To determine these, the crucial step is to evaluate (31)  along the equipotential (26) labeled by K = m, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' for  z =  �  mf ′(α) eiα with α ∈ [0, 2π), where as usual we  assume m ≫ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, if (31) holds on a level curve,  then it holds for all z by holomorphicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is writ-  ten in more detail in App.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' C, where we show that the  integrand of (31) has a saddle point at ϕ = α, eventu-  ally resulting in a transport equation for the unknown  function n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Here we skip the computation and analyse  separately the real and imaginary parts of the transport  equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We start with the real part, which will allow  us to deduce the LLL-projected energy spectrum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The  imaginary part is postponed to Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV D, where we also  display the resulting nearly Gaussian wave functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Let Φ(ϕ) denote the phase of n(f(ϕ)) ≡ N(ϕ) eiΦ(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Then the real part of the transport equation [see (C17)]  yields  Φ′(ϕ) = E1  m  Ωm  f ′(ϕ) − 1  2  � Γm  Ωm  + 1  ��  1 + f ′′(ϕ)2  4f ′(ϕ)2  �  − 1  2 + ∂ϕ  � f ′′(ϕ)  8f ′(ϕ)  �  + 1  2  ∂ϕ[f ′′(ϕ)/2f ′(ϕ)]  1 + f ′′(ϕ)2/4f ′(ϕ)2 ,  (32)  where E1  m is the first order correction to the energy (9)  and we introduced the parameters  Ωm ≡ V ′  0(ℓ2m) > 0,  Γm ≡ ℓ2m V ′′  0 (ℓ2m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (33)  In many-body droplets with N electrons, these will re-  spectively measure the Fermi velocity and the curvature  of the potential at the Fermi surface when m = N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note  that all terms in (32) are total derivatives save for the  factor 1 + [f ′′/2f ′]2, so the solution is  Φ(ϕ) = E1  m  Ωm  f(ϕ) − 1  2  � Γm  Ωm  + 1  � � ϕ  0  dθ  �  1 + f ′′(θ)2  4f ′(θ)2  �  − ϕ  2 + f ′′(ϕ)  8f ′(ϕ) + 1  2 arctan  � f ′′(ϕ)  2f ′(ϕ)  �  + const.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (34)  This turns out to imply a quantization condition for en-  ergy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, when we initially introduced the function  n(θ) in (18), we mentioned that it must have a vanishing  winding number along the equipotential, so that all the  winding of the wave function is contained in the expo-  nential factor eimθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The phase Φ(ϕ) must therefore be  strictly 2π-periodic, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Φ(2π) = Φ(0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Using (34), this  fixes the first quantum correction of the energy (9):  E1  m  Ωm  = 1  2 +  � Γm  Ωm  + 1  � � dϕ  4π  �  1 + f ′′(ϕ)2  4f ′(ϕ)2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (35)  The latter generally generally depends on m through Γm  and Ωm in (33).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  A simplification only occurs in ‘har-  monic’ setups where Γm = 0 and the right-hand side of  (35) is an f-dependent constant, for all m [72].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In any  case, the full mth energy (9) in the semiclassical limit can  be written as  Em ∼ V0  �  ℓ2m  �  + ℓ2  2  �  Ωm +  �  Γm + Ωm  � � dϕ  2π  �  1 + f ′′(ϕ)2  4f ′(ϕ)2  ��  ,  (36)  reproducing the result announced in (12)–(13) with λ =  2f ′ and generalizing the isotropic value obtained for  f ′ = 1 [see (A3)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The leading-order Bohr-Sommerfeld  quantization condition (8) is manifestly satisfied, while  the first quantum correction can be expressed in terms  of a Maslov-like shift and an integral of the Laplacian,  confirming the general result in [55]:  Em = V0  �  ℓ2�  m + 1  2  ��  + ℓ2  4  � dϕ  2π f ′(ϕ)∇2V  ��  r2=2ℓ2(m+1/2)f ′(ϕ) + O(ℓ4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (37)  (In the language of [55], our ‘Maslov-like’ term actually  stems from an integral of the curvature of γm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=') It now  remains to write the corresponding wave functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Gaussian wave functions  As above, write n(f(ϕ)) = N(ϕ) eiΦ(ϕ) for the un-  known function of the WKB ansatz, with a norm N(ϕ) =  9  |n(f(ϕ))|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Then the imaginary part of the transport  equation [see (C18)] can be recast into  N ′(ϕ)  N(ϕ) = 1  4∂ϕ log  �  1  f ′(ϕ)  �  1 + f ′′(ϕ)2  4f ′(ϕ)2  ��  ,  (38)  which remarkably has the form of an overall logarithmic  derivative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The general solution is thus  ��n  �  f(ϕ)  ��� = N0  �  1  f ′(ϕ)  �  1 + f ′′(ϕ)2  4f ′(ϕ)2  ��1/4  ,  (39)  where the normalization N0 will soon be fixed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note the  exponent 1/4, typical of WKB approximations [56].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We can now use (39) to evaluate approximate eigen-  functions (30) near their maximum, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' close to the  equipotential (C2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' To see this, zoom in on the equipo-  tential by writing  z ≡  �√m + a  ��  f ′(α) eiα  (40)  for m ≫ 1 and some finite a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The integral (30) then has  a unique saddle point at ϕ = α−iδ1/√m+O(1/m), with  δ1 = a  �  1 − i f ′′(α)  2f ′(α)  �−1  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The saddle-point approximation  of the wave function (30) thus yields  ψm(z, ¯z) ∼  1  √  2πℓ2  1  (2πm)1/4 eimf(α)+iΦ(α)  ×  1  �  σ(α)  exp  �  �− f ′(α) a2  1 − i f ′′(α)  2f ′(α)  �  � ,  (41)  where we used Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (34)–(39) for the phase and norm of  n(f(α)), fixed the integration constant in (39) to N0 =  1  2πℓ( m  2π)1/4, and introduced the ubiquitous width  σ(ϕ)2 ≡  1  f ′(ϕ)  �  1 + f ′′(ϕ)2  4f ′(ϕ)2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (42)  This is the angle-dependent variance of the probability  density of (41), written in (12) in terms of λ = 2f ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In-  deed, one has  |ψm(z, ¯z)|2 ∼  1  2πℓ2  e−2a2/σ2(α)  √  2πm σ(α),  (43)  which  satisfies  the  desired  normalization  condition  �  d2x |ψ|2 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note that Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (41) reproduces the wave  function stated in (11), once more with λ = 2f ′ and now  involving the phase  Θm(x) = mf(ϕ) + Φ(ϕ) −  a2f ′′(ϕ)  2f ′(ϕ)σ(ϕ)2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (44)  The Gaussian behavior of LLL-projected is thus mani-  fest, as anticipated at the end of Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III B for the gen-  eral WKB ansatz (20).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It is illustrated in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 3 for two  choices of the confining potential (25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Finally, (41) gen-  eralizes the behavior of isotropic states (3) [see (A1)], in-  cluding the O(1/√m) contribution that we did not state  here but that can be computed by incorporating the next  order term δ2/m for the saddle point and repeating the  analysis [73].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Out[� ]=  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='6  0  1  |ψm|2  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The density of a wave function (41) at m = 30 in an  edge-deformed trap (25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The Gaussian behavior is manifest,  as is the angle-dependent ‘roller coaster’ predicted by (43).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Left: Elliptic potential given by (25) with f of the form (24)  and k = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Right: Same edge-deformed trap as in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 1–2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Comparison with elliptic wave functions  To conclude this section, we now focus on the ‘flower’  deformations (24) and show that the resulting transport  equation is integrable: both the phase (34) and the norm  (39) can be expressed in terms of elementary functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  These results are valuable in themselves since flower maps  are the simplest edge deformations—they are analogues  of Fourier modes for circle diffeomorphisms—, but also  because their special case k = 2 reproduces known wave  functions in elliptic harmonic traps [68, 74], providing an  important benchmark for our WKB approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Consider first the deformation (24) with α = cosh λ  and β = sinh λ for an arbitrary integer k and a real pa-  rameter λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then the energy quantization condition (35)  can be integrated exactly, yielding  E1  m  Ωm  = 1  2 + 1  2  �  1 + Γm  Ωm  ��  1 + k2  4  �  cosh(2λ) − 1  ��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (45)  As for the solution of the transport equation, consisting  of the phase (34) and norm (39), it is found to be  n(θ) = N0 e  i  8  Γm  Ωm k sin(kθ) sinh(2λ)e  i θ  2  �  (  Γm  Ωm +1)  �  1− k2  4  �  +1− k  2  �  ×  �cosh λ + eikθ sinh λ  eikθ cosh λ + sinh λ  � k2−4  8k (1+ Γm  Ωm )− 1  2k + 1  4  ×  �  −4eikθ + (e2ikθ − 1)k sinh(2λ)  eikθ cosh λ + sinh λ  (46)  up to an overall constant phase.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that (46) depends in a non-trivial way on the po-  tential derivatives (33), with some simplification in the  ‘harmonic’ regime Γm = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Let us therefore apply Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (45)–(46) to the case of an elliptic potential k = 2 with  constant stiffness Ωm = Ω > 0 (hence Γm = 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The cor-  responding edge deformation (23) maps the isotropic har-  monic potential V0(x) = Ω r2/2 on its anisotropic cousin,  V (x) = Ω e−2λx2 + e2λy2  2 cosh(2λ)  ,  (47)  10  whose equipotentials are ellipses rather than circles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The  energy correction (45) then becomes E1  m =  1  2Ω[1 +  cosh(2λ)] and the solution (46) of the transport equation  can be written as  n(θ) = N0  �  cosh λ − e2iθ sinh λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (48)  It is straightforward to use this data to obtain the elliptic  version of the normalized Gaussian wave function (41):  ψm(z, ¯z) ∼  �2π  m  �1/4  1  2πℓ  eimθ  √  cosh λ − e−2iθ sinh λ  × exp  �  −e2iθ + tanh(λ)  e2iθ − tanh(λ)a2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (49)  Crucially, the latter coincides with the large m approxi-  mation of the exact LLL-projected eigenstates of the har-  monic potential (47), as can be verified thanks to known  asymptotic formulas for Hermite polynomials [68].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This  is actually true even at subleading order in 1/√m, which  we omit here for brevity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  MANY-BODY OBSERVABLES  This section finally applies the results of Secs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' III–IV  to fully-fledged QH droplets consisting of a large num-  ber N ≫ 1 of electrons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Specifically, we exploit our  insights on near-Gaussian single-particle wave functions  (41) to compute many-body observables and read off the  universal shape-dependent effects implied by the width  (42).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The density is treated first: it equals  1  2πℓ2 in the  bulk, then drops to zero as an error function at the edge  redge = ℓ  �  2Nf ′(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We then turn to the current and  show that it is localized as a Gaussian on the edge, to  which it is tangent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Third, correlations near the edge  are found to display the usual power-law behavior of free  fermions, dressed by radial Gaussian factors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This re-  duces to known expressions in isotropic traps [59] and in  the case of flower deformations (24) with k = 2, where  one recovers the elliptic results of [68, 74].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Finally, the  radial behavior of correlations is shown to be consistent  with the effective low-energy field theory of edge modes:  we derive it microscopically and obtain a chiral CFT in  terms of the angle variable on the boundary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Density  Consider a QH droplet of N ≫ 1 non-interacting 2D  electrons subject to the Hamiltonian (1), with a very  strong magnetic field B = dA and a weak edge-deformed  potential (25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The ground state of this many-body sys-  tem is a Slater determinant of the wave functions ψm for  occupied states m = 0, 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' , N −1, where we recall that  m is a quantized action variable generalizing angular mo-  mentum (see the red dots in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Each ψm yields a  m  Energy  ◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦••••  N  Fermi energy  ••••••••◦◦◦◦◦◦· · ·  ◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦◦· · ·  2Λ  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The one-body spectrum (37), where the states that  are occupied in the many-body ground state are highlighted in  red and those that contribute to the low-energy Hamiltonian  (64) are filled (black for ‘particles’, red for ‘holes’).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The cutoff  Λ is large but much smaller than N in the sense that Λ = O(1)  in the thermodynamic limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  single-particle probability density |ψm(x)|2, the sum of  which gives the many-body density  ρ(x) =  N−1  �  m=0  |ψm(x)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (50)  While WKB theory does not give access to the form of ψm  at low m, large values of m should be correctly captured  by the analysis of Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' IV, in which case the one-body  density is approximately Gaussian and given by (43).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We  now exploit this Gaussian form to evaluate the many-  body density, both in the bulk and close to the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (Some technical details are highlighted along the way, as  the same method will later allow us to study the many-  body current and correlations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=')  The key point is that each wave function (43) is local-  ized on an equipotential of V (x) with area 2πℓ2m, so the  density close to some equipotential |z| = const ×  �  f ′(ϕ)  only receives sizeable contributions from wave functions  whose quantum number is close to |z|2/f ′(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Accord-  ingly, the bulk density for 1 ≪ |z| ≪  √  N is obtained by  letting the upper summation bound of (50) go to infinity  and writing the approximate density as  ρ(x) ∼  1  2πℓ2  ∞  �  m=m0  e  −  2  σ2(ϕ)  �  |z|  √  f′(ϕ) −√m  �2  √  2πm σ(ϕ)  ,  (51)  where the lower summation bound m0 ≫ 1 is irrele-  vant as long as it is much smaller than |z|2, and σ(ϕ) is  the angle-dependent width (42).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' At large |z|, the Euler-  Maclaurin formula allows us to approximate the sum over  m by a (Gaussian) integral over √m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This yields the ex-  pected density  ρ(x) ∼  1  2πℓ2  (52)  in the bulk of a QH droplet with filling fraction ν = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  An analogous argument can be carried out close to  the droplet’s edge, with one key difference: the upper  summation bound of (50) is now crucial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Thus, letting  |z| =  �√  N + a  �  f ′(ϕ) with finite a in the large N limit  11  and using once more the approximate Gaussian behavior  (43), the density (50) near the edge behaves as  ρ(x) ∼  1  2πℓ2  ∞  �  k=1  e  −  2  σ2(ϕ)  �  a+  k  2  √  N  �2  √  2πN σ(ϕ)  ,  (53)  where we changed variables as m ≡ N − k with k =  O(  √  N) at large N and only kept track of leading-order  terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For N ≫ 1, the sum over k can once more be  converted into an integral, now over k/2  √  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This yields  the asymptotic behavior  ρ(r, ϕ) ∼  1  4πℓ2 erfc  �  1  σ(ϕ)  r − ℓ  �  2Nf ′(ϕ)  ℓ  �  f ′(ϕ)  �  (54)  where erfc denotes the complementary error function and  the width (42) is inherited from that of LLL wave func-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is a remarkably explicit result, announced in  (14) with λ = 2f ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It confirms that the density is roughly  constant and equal to (52) in the bulk, then drops to zero  within a distance of the order of the magnetic length (2)  around the edge at r = ℓ  �  2N f ′(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' See Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 2(a)–5(a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We stress that, in contrast to wave functions, the den-  sity (54) only depends on the potential near the edge of  the droplet: bulk deformations of the potential do not af-  fect the quantized bulk density (52) in the limit of strong  magnetic fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In this sense, (54) is a universal formula  for the density of any QH droplet of LLL states whose  edge traces an equipotential of the form r2 = 2ℓ2N f ′(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  It would be instructive to probe this local density in mod-  ern quantum simulators [21–24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that the leading-order formula (54) receives a  number of subleading corrections that can be systemati-  cally computed in our formalism;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' these are omitted here  for brevity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' A related comment is that the bulk value  density (52) is only valid at extremely strong magnetic  fields, which stems from the simplification provided by  the LLL projection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The actual density profile depends  on the gradient of the potential, but this involves higher  Landau levels that are beyond our scope [28, 29].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Current  The current of a droplet of N ≫ 1 electrons can simi-  larly be evaluated as a sum over single-particle currents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  To this end, recall that the gauge-invariant one-body  probability current of a charged wave function ψ with  mass M is a one-form ℏ j/M given by  j = 1  2i  �  ψ∗dψ − ψdψ∗ − 2iq  ℏA|ψ|2�  ,  (55)  where the first term is only sensitive to the phase of ψ  and A = 1  2Br2 dϕ = ℏ  q |z|2 dϕ in symmetric gauge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Thus,  the many-body current of a Slater determinant of the  occupied states ψm with m = 0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' , N − 1 is  J =  N−1  �  m=0  jm,  (56)  where jm is the single-particle current (55) of each ψm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  As before, the WKB approximation does not give ac-  cess to wave functions for small m, but this is unim-  portant close to the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In that regime, we have al-  ready gathered all ingredients needed to evaluate the  currents (55) up to small quantum corrections: the one-  body density is given by (43), while the derivative of  the phase is contained in (41) and the phase transport  equation (32).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In practice, the WKB phase Φ turns  out to be negligible at leading order, and the only rel-  evant parts of the phase are those already visible in (41):  the (fast) phase eimf(ϕ) together with the contribution  from A =  �  ℏ|z|2/q  �  dϕ eventually gives rise to the lead-  ing ϕ component of the current, while the (slow) phase  e−i[f ′′(ϕ)/2f ′(ϕ)]a2/σ2 yields its radial component that is  non-zero whenever f ′′(ϕ) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Starting from these facts, it is straightforward to adapt  the method of Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' V A to the many-body current (56).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Writing |z| =  �√  N +a  ��  f ′(ϕ), the sum over m ≡ N −k  becomes an integral over k/(2  √  N) = O(1), which yields  the leading order result quoted in (15) with λ = 2f ′:  J(r, ϕ) ∼ −  e  −  2a2  σ(ϕ)2  (2πℓ2)3/2σ(ϕ)  ℓ  �  2Nf ′(ϕ) dϕ + f ′′(ϕ)  2f ′(ϕ) dr  �  2f ′(ϕ)  (57)  where a =  �  r−ℓ  �  2Nf ′(ϕ)  ��  ℓ  �  2f ′(ϕ) and σ(ϕ) is given  by (42).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Both components in (57) receive subleading cor-  rections that are omitted here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In particular, there is an  O(1) term in Jϕ that is non-zero on the edge, even in the  isotropic case f ′ = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The computation of that term re-  quires the O(1/√m) correction that was omitted in (43).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Using the metric ds2 = dr2 + r2dϕ2, one verifies that  the one-form ℓ√2N f ′ dϕ+(f ′′/2f ′) dr in (57) is the dual  of a vector tangent to the equipotential at the droplet’s  edge [75].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Moreover, the norm squared of (57) is  ∥J(r, ϕ)∥2 ∼  1  2(2πℓ2)3 exp  �  −2  �  r − ℓ  �  2Nf ′(ϕ)  �2  ℓ2σ(ϕ)2f ′(ϕ)  �  ,  (58)  showing that the current has a constant maximum along  the edge but a varying width: see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Similarly to the density, it is important to remember  that the LLL projection misses some important physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Indeed, the actual bulk current is the symplectic gra-  dient of the confining potential multiplied by the Hall  conductance [28, 29, 41, 42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  No such effect occurs in  (57) because it requires higher Landau levels, which are  beyond our scope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Correlations  The methods that we have applied to density and cur-  rent can also be used to compute electronic correlations  near the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, consider as before an anisotropic  droplet whose occupied one-body states have quantum  12  ���  ���  ���  x  x  x  y  y  y  √  N  −  √  N  −  √  N  √  N  (a)  (b)  (c)  x  x  x  y  y  y  ℓ  √  2N  −ℓ  √  2N  −ℓ  √  2N  ℓ  √  2N  Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (a) The density (54) for N = 100 electrons and a ‘flower’ edge deformation (24) of order k = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The constancy of  density in the bulk and its sharp decay at the boundary are manifest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (b) The current’s norm (58) for the same flower-shaped  droplet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The localization on the edge equipotential (black line) is clearly visible, as is the position-dependent width of the  Gaussian jump.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (c) The correlation function C(x1, x2) (61) for the same flower-shaped droplet, seen as a function of x2 when  x1 = (ℓ  �  Nλ(0), 0) is fixed close to the edge of the droplet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  numbers m = 0, 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' , N − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then the correlation func-  tion between the points x1 and x2 is  C(x1, x2) =  N−1  �  m=0  ψ∗  m(x1) ψm(x2),  (59)  which reduces to the density (50) when x1 = x2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  As  before, we rename m ≡ N − k and let the complex coor-  dinates z, w corresponding to x1, x2 be such that  z =  �√  N + a  ��  f ′(ϕ1) eiϕ1,  w =  �√  N + b  ��  f ′(ϕ2) eiϕ2,  (60)  where a, b are finite at large N and ϕ1, ϕ2 are the po-  lar angles of x1, x2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  One can then plug the Gaussian  wave functions (41) into (59), this time assuming k fi-  nite, and performing the sum over k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The gradient ex-  pansion of the potential implies that the ratio Γm/Ωm ∼  ΓN/ΩN + O(ℓ2) is nearly constant in this regime, so Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (59) becomes a geometric sum over k that reproduces the  result stated in (16) with λ = 2f ′:  C(x1, x2) ∼  eiΘN(x1,x2)  (2π)3/2ℓ2√  N  1  �  σ(ϕ1)σ(ϕ2)  ×  i e  −  a2  σ(ϕ1)2 −  b2  σ(ϕ2)2  2 sin  �  [f(ϕ1) − f(ϕ2)]/2  �,  (61)  where σ(ϕ) is the angle-dependent width (42).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The over-  all phase ΘN(x1, x2) = ΘN(x2) − ΘN(x1) is given by  (44), and involves in particular the WKB phase (34).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Some features of (61) are worth emphasizing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' First,  note  the  Gaussian  jump  of  power-law  correlations  near the edge, involving a free fermion correlation ∝  sin([f(ϕ1)−f(ϕ2)]/2)−1 expressed in terms of f(ϕ1) and  f(ϕ2);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' this is the standard static diagnostic of the pres-  ence of edge modes [10, 59, 76].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' A second striking aspect  is the apparent lack of translation-invariance along the  edge, caused not only by the argument f(ϕ1) − f(ϕ2) =  � ϕ1  ϕ2 dθ f ′(θ) but also by the widths σ(ϕ1) and σ(ϕ2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In  particular, the product σ(ϕ1)−1/2σ(ϕ2)−1/2 is reminis-  cent of prefactors picked up by primary fields in CFT  under conformal maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Since the boundary correlator (61) holds in any edge-  deformed trap (25), it also applies to special cases of in-  terest such as the anisotropic harmonic potential (47).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The corresponding correlations were actually computed  long ago in [68], and they coincide with our result (61)  upon using the map (24) with k = 2, α = cosh λ,  β = sinh λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In fact, this specific setup is also well known  in the context of the Coulomb gas, since edge correla-  tions can then be related by a conformal map to the  standard Euclidean correlation function (z1 − z2)−1 of a  free fermion CFT [77].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Finally,  it is a simple matter to include time-  dependence in the correlator (61).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, the occupied  one-particle states in (59) have definite energies Em given  by (37) at large m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This spectrum is approximately linear  close to the Fermi energy: changing variables according  to m = N + k with k finite at large N, one has  EN+k − EN ∼ ℏω k  (62)  where ω ≡ ℓ2ΩN/ℏ is the angular Fermi velocity given  by the derivative (33) at m = N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that ω re-  ceives a number of subleading quantum corrections in-  volving e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' the curvature ΓN in (33) [78–80];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' we ne-  glect those.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In the linear regime (62), one can repeat  the asymptotic computation of the correlator and find 1  1  1  1 4  r 1  1  1  1  1  1 1 1  1 1  1  1  113  once more a result of the form (61), now with a time-  dependent overall phase and a time-dependent denom-  inator 2 sin  �  [f(ϕ1) − f(ϕ2) − ω(t1 − t2)]/2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This ex-  hibits the standard ballistic propagation of correlations  in a CFT, which we confirm below by deriving the effec-  tive low-energy dynamics of our droplet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Edge modes  The effective low-energy description of anisotropic QH  droplets can be derived similarly to the isotropic case  [59] inspired by Luttinger-liquid theory [81].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This has  the advantage of circumventing topological field theory,  at the cost of failing to apply in fractional QH states [6–  10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We now provide such a first-principles calculation,  eventually concluding that edge modes span a free chiral  CFT expressed in terms of the angle coordinate f(ϕ)  along the boundary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Aside from its intrinsic interest,  this computation provides an independent check of the  validity of the correlation (61).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Our starting point is the second-quantized Hamilto-  nian in a Fock space of free fermions,  H =  �  m,n  (Em,n − µ)a†  m,nam,n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (63)  Here the sum runs over eigenstates of the one-body  Hamiltonian (1), labeled by the Landau level n ∈ N  and the ‘action variable’ quantum number m ∈ N within  each level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Their energies are denoted Em,n, and µ is  some chemical potential to be fixed below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  For each  pair (m, n), the operator a†  m,n creates the corresponding  eigenstate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The exact energy spectrum is unknown, but  this is not an issue since low-energy excitations all be-  long to the LLL, with an approximately linear dispersion  (62) within a window [−Λ, Λ] around the Fermi momen-  tum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then choosing the chemical potential of (63) as  µ = const − 1  2ℏω, the low-energy approximation of the  many-body Hamiltonian (63) becomes  H ∼  �  k∈[−Λ,Λ]  ℏω (k + 1/2) a†  N+kaN+k,  (64)  where the sum is over all integers k in the specified win-  dow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Since aN+k are fermionic Fock space operators, the  Λ → ∞ limit of (64) yields a gapless Hamiltonian for free  fermions written in Fourier modes, and the chemical po-  tential enforces antiperiodic (Neveu-Schwarz) boundary  conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It now only remains to relate the edge CFT  to bulk wave functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  To this end, note that the Fock space operators in (64)  create states in the LLL that are given by the Gaussian  wave function (41).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' One can therefore express them in  terms of 2D creation operators c†(x):  a†  N+k ∼  � f ′(ϕ) dϕ  √  2π  ei(k+1/2)f(ϕ) Ψ†(f(ϕ)),  (65)  where the 1D fermionic field Ψ is defined as a radial in-  tegral involving the wave function (41),  Ψ†(f(ϕ)) ≡ ei(N−1/2)f(ϕ) eiΦ(ϕ)  f ′(ϕ)  �  σ(ϕ)  ×  � ∞  0  r dr  ℓ(2πN)1/4 c†(x) e  −  1  σ2(ϕ)  �  r  √  2ℓ2f′(ϕ) −  √  N  �2  (66)  with σ the width (42) and Φ the WKB phase (34).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note  that in writing (66) we assumed that the momentum in-  dex k and the cutoff Λ are of order O(1) in the thermo-  dynamic limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It is then clear that the operator Ψ†(ϕ)  creates an electron at the position ϕ on the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  From this point onward, the derivation of the low-  energy effective field theory is essentially done.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed,  the Hamiltonian (64) expressed in terms of the edge field  (66) reads  H = ℏω  �  dθ Ψ†(θ) (−i∂θ)Ψ(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (67)  Furthermore, the normalization of the field Ψ defined by  (66) is canonical in angle variables: using the standard  anticommutator {c(x1), c†(x2)} = δ(2)(x1 −x2), one sim-  ilarly finds {Ψ(f(ϕ1)), Ψ†(f(ϕ2))} = δ(f(ϕ1) − f(ϕ2)) in  terms of the Dirac delta function on a circle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This de-  termines the kinetic term of the action functional for Ψ,  which is thus a canonical fermionic expression ∼ Ψ†∂tΨ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  It can be combined with the Hamiltonian (64) to write  down the fermionic action functional of edge modes,  S[Ψ, Ψ†] = ℏ  �  dt dθ iΨ†(θ)  �  ∂t + ω∂θ  �  Ψ(θ),  (68)  where we recall that the angular Fermi velocity is ω =  ℓ2ΩN/ℏ, given by (33).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is manifestly a (1+1)D free  chiral CFT in terms of the angle variable θ = f(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The low-energy effective theory (68) is universal: for  any trapping potential, edge modes are described by a  chiral fermionic CFT expressed in terms of the angle co-  ordinate of the trap at the boundary, as could have been  guessed from the dynamics of electronic guiding centers  induced by the potential V in the non-commutative plane  (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In the present case, the angle coordinate was just  θ = f(ϕ);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' more general cases involve more complicated  action-angle variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We stress that the angle variable  generally has nothing to do with other obvious position  coordinates, such as the polar angle ϕ or the arc length  s(ϕ) = ℓ  √  2N  � ϕ  0  dα  �  f ′(α) + f ′′(α)2  4f ′(α) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (69)  Any such ‘wrong’ coordinate makes the apparent Fermi  velocity of edge modes position-dependent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is rem-  iniscent of inhomogeneous CFTs whose light-cones are  curved owing to the presence of a non-zero space-time  curvature [82–89].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  However, one should keep in mind  that our edge modes sense a flat metric ω2dt2 − dθ2 =  14  ω2dt2 − f ′(ϕ)2dϕ2 whose light-cones are straight lines in  terms of the angle variable θ = f(ϕ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Let us conclude this section by showing that the action  (68) is consistent with the seemingly complicated corre-  lator (61).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We start from the definition (66) to write the  1D correlation function ⟨Ψ†(θ1)Ψ(θ2)⟩ as a double radial  integral of the 2D quantity ⟨c†(x1)c(x2)⟩.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Now using the  asymptotic relation (61), one finds that all normaliza-  tions simplify and the correlator of the edge field boils  down to  ⟨Ψ†(θ1)Ψ(θ2)⟩ = 1  2π  i  2 sin  �  [θ1 − θ2]/2  �.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (70)  The same result would have been obtained directly from  the low-energy action (68): it is a correlation function  of free gapless fermions written in terms of the angle  coordinates θ1 = f(ϕ1) and θ2 = f(ϕ2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As a bonus,  time-dependent correlations automatically satisfy the be-  haviour ∝ sin  �  [θ1 − θ2 − ω(t1 − t2)]/2  �−1 stated at the  end of Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' V C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  CONCLUSION AND OUTLOOK  This work was devoted to a detailed study of meso-  scopic droplets of non-interacting planar electrons placed  in a perpendicular magnetic field and confined by star-  shaped anisotropic traps with scale-invariant level curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In particular, we provided explicit formulas for the corre-  sponding wave functions and energy spectrum, allowing  us to compute the many-body density, current, and cor-  relations of an entire droplet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The resulting low-energy  edge modes were eventually shown to behave as a chiral  CFT in terms of the angle variable along the boundary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This was all achieved in a regime of high magnetic fields,  ultimately equivalent to a semiclassical limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  These results pave the way for a number of applications  and follow-ups.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Indeed, recent advances in quantum sim-  ulation suggest the tantalizing possibility of probing lo-  cal properties of QH-like droplets in the lab [21–24], both  for static ground states and their dynamical edge excita-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The density (54) or the current (57) then predict  observable shape-dependent widths, while the low-energy  theory (68) predicts the ballistic propagation of local  boundary disturbances with a position-dependent veloc-  ity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' More generally, the geometry of the QH effect [33–  39] could soon become relevant for experiments involv-  ing ultracold atoms or photonics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Our framework pro-  vides a bridge between this field of mathematical physics  and concrete observables in mesoscopic quantum physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Verifying the predictions put forward here, through lin-  ear response experiments or direct imaging, would be a  fascinating example of many-body quantum mechanics  at work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Turning now to theory, the link between our formal-  ism and QH symmetries deserves further study: following  the series of works [58–63], one can think of edge defor-  mations as approximately unitary operators acting on  many-body QH states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It is then natural to wonder how  these operators get composed together;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' do they span a  Virasoro group as in CFT?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' If yes, how to derive the cen-  tral charge c = 1 in terms of microscopic wave functions?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  More broadly, what are the operators implementing area-  preserving deformations in the sense of the WKB ansatz  (20)?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' One expects these operators to provide a finite (ex-  ponentiated) form of the operators studied in [58, 60, 61],  with non-commutative composition laws consistent with  the geometry (6) of LLL physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that the discussion above was mostly focused on  leading-order properties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For instance, one may wonder  what are irrelevant corrections to the edge field theory  (68), especially following the recent numerical observa-  tion [79] that density waves on the edge satisfy a non-  linear Korteweg-de Vries equation at late times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This  regime is presumably described by small droplet defor-  mations of the form r2 �→ r2 + α(ϕ), spanning a U(1)  Kac-Moody algebra whose level is sensitive to the fill-  ing fraction [58, 60, 61].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The resulting non-linear edge  waves would then be described by an evolution equa-  tion in an infinite-dimensional group manifold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This per-  spective is standard in hydrodynamics [90–92], but it  has only recently come to be appreciated in condensed  matter physics [93].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The geometric study initiated here  provides a basis for considerations of this kind in the  QH effect, including the possibility of inhomogeneous  (position-dependent) corrections in anisotropic traps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Another obvious extension of this work is the fractional  QH regime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In that context, no single-particle descrip-  tion is available, but many-body predictions such as the  edge density (54) or the current (57) conceivably display  universal geometric features that would remain true in  interacting many-body ground states [42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It would be  thrilling to derive such predictions from the family of  edge transformations studied here, either from a micro-  scopic analysis of the Laughlin wave function, or thanks  to the reformulation of fractional QH states as CFT cor-  relation functions [94].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  ACKNOWLEDGMENTS  We are grateful to Laurent Charles for illuminating  discussions on semiclassical methods in Kählerian geo-  metric quantization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' also thanks Mathieu Beauvil-  lain, Nathan Goldman, and Marios Petropoulos for col-  laboration on closely related subjects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Finally, we ac-  knowledge useful and motivating interactions with Jean  Dalibard, Benoit Douçot, Jean-Noël Fuchs, Marc Geiller,  Gian Michele Graf, Semyon Klevtsov, Titus Neupert  and Nicolas Regnault.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The work of B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' is supported  by the European Union’s Horizon 2020 research and in-  novation programme under the Marie Skłodowska-Curie  grant agreement No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 846244.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' acknowledges fund-  ing from the European Research Council (ERC) under  the European Union’s Horizon 2020 research and inno-  vation program (Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' ERC-StG-Neupert-757867-  15  PARATOP).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' gratefully acknowledges financial sup-  port from the Wenner-Gren Foundations (No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' WGF2019-  0061).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' is supported by the ANR grant TopO No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  ANR-17-CE30-0013-01.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Appendix A: Isotropic droplets  Most of this work is concerned with anisotropic prop-  erties, so isotropic results provide a useful benchmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  They are simpler than their anisotropic counterparts and  mostly well-known in the literature, so their properties  are concisely summarized here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We begin by recalling el-  ementary aspects of the one-body energy spectrum based  on the exact wave functions (3), then turn to many-body  observables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  One-body spectrum  Consider a spin-polarized 2D electron governed by the  Landau Hamiltonian (1) with an isotropic confining po-  tential V (x) = V0(r2/2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' At very strong magnetic fields,  the resulting one-body spectrum is well approximated  by the solution of the LLL-projected eigenvalue equa-  tion (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As the potential is isotropic, it commutes with  angular momentum, so the eigenstates of P V P are wave  functions (3) with definite angular momentum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note that  these confirm the general near-Gaussian behavior found  in (43): letting |z| = √m+a with finite a, one finds that  (3) behaves at large m as  φm(x) =  eimϕ  √  2πℓ2  1  (2πm)1/4 e−a2 �  1 + O(1/√m)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (A1)  The energy Em of each state (3) is readily found by com-  puting the wave function ⟨z, ¯z|PV0(r2/2)P|φm⟩, which  yields the exact eigenvalue  Em = ⟨φm|V |φm⟩ = 1  m!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  � ∞  0  dt tm e−t V0(ℓ2t)  (A2)  in terms of the integration variable t ≡ |z|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note in pass-  ing that this is the value one would find from first-order  perturbation theory of the full Landau Hamiltonian (1):  by construction, LLL-projected physics is only sensitive  to first-order effects of the potential, while higher-orders  ultimately involve higher Landau levels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Now fix an index m ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' What is the corresponding  equipotential in the sense of (9)?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' To answer this in the  classical limit, we let m → ∞ while fixing the value of  ℓ2m = O(1), and evaluate the integral (A2) thanks to a  saddle-point approximation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The result is  Em = V0(ℓ2m) + ℓ2Ωm + ℓ2  2 Γm + O(ℓ4),  (A3)  where Ωm and Γm were defined in (33).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is consistent  with Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (13) and (36) with λ = 2f ′ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Many-body aspects  The sequence followed here is the same as in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' V: we  start with the density, then consider the current and cor-  relations close to the edge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In all cases, the edge asymp-  totics reproduce the formulas of Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' V for the simplest  case where f ′(ϕ) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Let N ≫ 1 non-interacting planar electrons  be subjected to the Hamiltonian (1), with a very strong  magnetic field B = dA and a weak isotropic poten-  tial V (x) = V0(r2/2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The ground state wave func-  tion of this many-body system is a Slater determinant of  the occupied single-particle eigenstates φ0, φ1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' , φN−1  given by (3), each of which has a one-body density  |φm(x)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The resulting many-body density is thus (50),  which can be computed in closed form in the very spe-  cial case of states (3) with definite angular momentum:  it is a normalized incomplete gamma function ρ(x) =  (2πℓ2)−1Γ(N, |z|2)/Γ(N).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Constancy of density in the  bulk is then manifest, as is its drop to zero close to  the edge |z| =  √  N, with an error function behavior  that can be deduced from known asymptotic formulas  for gamma functions [76] and reproduces Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (14)–(54)  with λ = 2f ′ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For the LLL states (3) with definite angular  momentum, each one-body current (55) is purely angu-  lar, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' it reads jm = (.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' )dϕ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The sum (56) can then  be evaluated in closed form owing to an exact cancella-  tion between the contribution of the states m and m+ 1,  eventually leading to a current only due to the (N − 1)th  wave function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' It is then trivial to show that the current  is localized as a Gaussian close to the edge, since this is  also true of the underlying single-particle wave function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This reproduces Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (15)–(57) with λ = 2f ′ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Correlations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The computation of electronic correla-  tions close to the edge is similar to that of the density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Indeed, since the many-body ground state wave function  is a Slater determinant, the two-point correlation func-  tion in the ground state can be expressed as in (59).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The  exact wave functions (3) can then be used to write the  correlation (59) as an incomplete gamma function (this  time with a complex argument):  C(z, ¯z, w, ¯w) =  1  2πℓ2  Γ(N, ¯zw)  Γ(N)  e−(|z|2+|w|2)/2 ez ¯  w.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (A4)  It is then manifest that bulk correlations coincide with  the kernel (5) at leading order in the thermodynamic  limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As for the edge behavior, it can be extracted e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  from a steepest descent argument [76] and reproduces  Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (16)–(61) with λ = 2f ′ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Appendix B: Semiclassical expansion of P V P  In this appendix, we derive (22) starting from (21).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  To this end, think of V (x, y) as some smooth function of  16  (x, y) whose arguments can be complexified, and change  the integration variables (x, y) of (21) to  s ≡ x −  ℓ  √  2(z + ¯w),  t ≡ y +  iℓ  √  2(z − ¯w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (B1)  In terms of (s, t), the integrals in (21) are two line in-  tegrals in the complex plane, each along a path from  −∞ + ic to +∞ + ic, where c is some irrelevant real con-  stant (a different one for s and t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The advantage of the  change of variables (B1) is to make the exponential factor  in (21) purely Gaussian:  ⟨z, ¯z|P V (x)P|w, ¯w⟩ =  1  (2πℓ2)2 e− |z−w|2  2  e  z ¯  w−¯zw  2  ×  �  ds dt V  �  s+ ℓ  √  2(z + ¯w), t− iℓ  √  2(z − ¯w)  �  e− s2+t2  2ℓ2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (B2)  We then complexify V , thus replacing V (x, y) by V(z, ¯z),  where V(z, ¯w) is a function of two complex variables,  holomorphic in the first one and anti-holomorphic in the  second.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We can then deform independently both inte-  gration contours for s and t back to the real line.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For  small ℓ, the Gaussian factor of (B2) localizes everything  to s = t = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We now use our assumption of slow varia-  tion of V (x) to Taylor-expand it as  V  �  s +  ℓ  √  2(z + ¯w), t −  iℓ  √  2(z − ¯w)  �  ∼  �  V + s2  2 ∂2  xV + t2  2 ∂2  yV  ����� ℓ  √  2 (z+ ¯  w),− iℓ  √  2 (z− ¯  w)  �,  (B3)  where we only kept terms that give non-zero contribu-  tions to the O(ℓ2) approximation of the integral (B2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that everything is evaluated at (x, y) = ( ℓ  √  2(z +  ¯w), − iℓ  √  2(z − ¯w));' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' in complex coordinates, this is just  the point (z, ¯w), so it is simpler to write the potential  as V(z, ¯w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Plugging the expansion (B3) into (B2) then  yields the result (22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Appendix C: The transport equation  The purpose of this appendix is to derive the real and  imaginary parts of the transport equation in (32) and  (38), respectively, by imposing the eigenvalue equation  (7) based on our WKB ansatz (30) in the case of edge-  deformed droplets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The derivation relies on expanding  the energy and the potential as in (9) and (22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  It is  divided in two parts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' First, we use the eigenvalue equa-  tion to derive the constraint (31), and let z belong to an  equipotential so that the whole equation boils down to  a 1D integral identity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Second, we show that the inte-  gral has a sharp saddle point in the large m limit;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' this  allows us to rephrase the integral constraint as a first-  order transport equation for the unknown function n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Evaluation along an equipotential  Using the wave functions (18)–(19) and the expansion  (22) of the potential along with the projector property  P 2 = P, the eigenvalue problem (7) reads  0 =  �  R2  d2w  2πℓ2 e− |z−w|2  2  + z ¯  w−¯zw  2  ��  V+ ℓ2  2 ∇2V  ����  (z, ¯  w)−Em  �  ×  �  dθ n(θ) eimθ δ2�  w −  �  F(m, θ), G(m, θ)  ��  (C1)  up to O(ℓ4) corrections [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In the case of edge-deformed  traps, V(z, ¯w) is the bicomplex potential given in (28)  and the delta function localizes the whole integral over  w to a level curve (27) with K = m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Integrating over w  and changing the integration variable from θ = f(ϕ) to  ϕ yields Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (31).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Note that the structure of Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (C1) and (31) is 0 =  e−|z|2/2 F(z) for a holomorphic function F(z), so setting  F(z) = 0 on a closed curve implies F(z) = 0 everywhere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Accordingly, we will solve (C1)–(31) along the equipo-  tential (26) by fixing K = m and parametrizing  z =  �  mf ′(α) eiα,  α ∈ [0, 2π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (C2)  This ensures that all three terms in the exponent of (31)  are of the same order O(m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Then (31) with the choice  (C2) and ϕ ≡ α + ε becomes  0 =  � π  −π  dε f ′(α + ε) n(f(α + ε)) exp  �  imf(α + ε) − 1  2mf ′(α + ε) + m  �  f ′(α)f ′(α + ε) e−iε�  ×  �  V  ��  mf ′(α) eiα,  �  mf ′(α + ε) e−i(α+ε)�  + ℓ2  2 ∇2V − E0  m − ℓ2E1  m  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (C3)  This rewriting will allow us to carry out the integral thanks to the saddle-point approximation, obtained by expanding  all terms in powers of ε and leading to a differential equation for n(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  17  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Saddle point and transport equation  The saddle-point expansion of the integral (C3) is cumbersome but straightforward.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The strategy is to expand all  factors in the integrand up to a suitable power of ε, then perform the resulting integrals of the form  �  dε ε# e−Cε2,  where C is some f-dependent coefficient [see e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (C5)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The powers of ε involved are typically small, as higher powers  are suppressed in the classical limit [large m and ℓ2m = O(1)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The fact that the argument of n(θ) also involves a  factor ε eventually converts the integral into a transport equation of the form n′(θ) ∝ n(θ) [see (C16)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  We start with (C3) and first expand the exponential, then the potential with its Laplacian, and finally the simplest  f ′(ϕ)n(f(ϕ)) prefactor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For convenience, we introduce the notation  A ≡ f ′′  f ′ ,  B ≡ f ′′′  f ′  (C4)  for combinations of derivatives of f that often appear below;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' from now on, expressions of the form f or f ′, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=', are  all implicitly evaluated at α unless specified otherwise (so f ≡ f(α), f ′ ≡ f ′(α), etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=').' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Note for future reference the  useful relation A′ = B − A2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The exponential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Using the notation (C4), one has  exp  �  imf(α + ε) − 1  2mf ′(α + ε) + m  �  f ′(α)f ′(α + ε) e−iε�  ∼ eimf+ 1  2 mf ′ exp  �  − 1  2mf ′ �  1 + A2  4  �  ε2� �  1 + mf ′ε3 �  i  6 − A  4 − iB  12 + iA2  8 − AB  8 + A3  16  ��  (C5)  where the factor exp  �  imf + mf ′/2  �  is ultimately irrelevant for the eigenvalue equation (C3), so we will not include  it in what follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' The main point of (C5) is to exhibit the leading Gaussian behavior exp  �  −(mf ′/2)(1 + A2/4)ε2�  of the integrand, which will eventually allow us to convert (C3) into a differential equation for the unknown function  n(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' In fact, the same exponential term appears in the approximately Gaussian wave function (43).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We now turn to the expansions of the potential and of its Laplacian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As a first step,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' our task is to  expand the potential  V  ��  mf ′ eiα,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  �  mf ′(α + ε) e−i(α+ε)�  = V0  �  �  �ℓ2m  √f ′ �  f ′(α + ε) e−iε  f ′  �  1  2i log  � √f ′ e2iα+iε  √  f ′(α+ε)  ��  �  �  �  ∼ V0  �  ℓ2m  �  1 − iε  �  1 + A2  4  �  + ε2 �  − 1  2 + B  8 − 3A2  8  − A3  4i − A4  16 + AB  4i + A2B  32  � ��  ∼ V0  �  ℓ2m  �  − iℓ2m ε  �  1 + A2  4  �  V ′  0  �  ℓ2m  �  − 1  2ℓ4m2ε2 �  1 + A2  4  �2  V ′′  0  �  ℓ2m  �  + ℓ2m ε2 �  − 1  2 + B  8 − 3A2  8  − A3  4i − A4  16 + AB  4i + A2B  32  �  V ′  0  �  ℓ2m  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (C6)  where we used (28) and then the notation (C4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Aside  from the contribution of the Laplacian, these are all the  terms of the potential needed in the eigenvalue equation  (C3) along an equipotential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' As expected, they all ul-  timately involve the potential and its derivatives at the  equipotential (26).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For ε = 0, the whole expression boils  down to V0(ℓ2m) alone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Let us now turn to the Laplacian term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  The  eigenvalue  equation  (C3)  requires  the  Laplacian  evaluated  at  the  complexified  point  (z, ¯w)  =  ��  mf ′(α) eiα,  �  mf ′(α + ε) e−i(α+ε)�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  In  practice,  the Laplacian term is multiplied by ℓ2 in (C3), so we  may safely set ε = 0 when computing it;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' this removes  the complexification and allows us to write the Laplacian  contribution in (C3) as  ℓ2  2 ∇2V ∼ ℓ2  f ′  �  1 − B  4 + A2  2  �  V ′  0(ℓ2m)  + ℓ4m  f ′  �  1 + A2  4  �  V ′′  0 (ℓ2m),  (C7)  which follows from the general expression (29) evaluated  on the equipotential (26).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  All together.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Let us finally consider the very first factor  on the right-hand side of (C3), namely  f ′(α + ε) n(f(α + ε)) ∼ f ′n(f) + ε  �  f ′′n(f) + f ′2n′(f)  �  (C8)  where higher powers of ε are negligible at this order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' To  see why they may be neglected, it is helpful to investigate  18  the general structure of the small ℓ expansion of (C3):  the exponential term in (C5) has the form  exp[imf(.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=')] ∼ const × e−mΛε2(1 + mLε3)  (C9)  with m ≫ 1 and Λ, L some O(1) coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Sim-  ilarly, the potential expansion (C6) together with the  Laplacian correction (C7) can schematically be written as  V0+ ℓ2  2 ∇2V0 ∼ V0+ℓ2W0+Gε+Hε2, where V0 ≡ V0(ℓ2m)  while W0, G, H are again some O(1) coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Finally,  the expansion (C8) of the prefactor roughly has the form  f ′n e(.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=') ∼ const × (f ′n + εIn′ + εJn),  (C10)  where I, J are O(1) coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  Putting together the  schematic expressions (C9)–(C10) and using the fact that  constant (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' ε-independent) contributions are irrelevant,  the eigenvalue equation (C3) becomes  0 =  �  dε (f ′n + εIn′ + εJn)e−mΛε2(1 + mLε3)  ×  �  V0 + ℓ2W0 + Gε + Hε2 − E0  m − ℓ2E1  m  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (C11)  Here the right-hand side is a sum of integrals whose in-  tegrand has the form εn e−mΛε2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' For odd n, each such  integral vanishes;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' for even n, it is non-zero and scales as  m−n/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' This is why only the first order in ε is needed in  the expansion (C8): higher powers of ε would yield sub-  leading corrections to (C11), which can be consistently  taken into account only by expanding the exponential,  potential and Laplacian terms up to orders in ε higher  than what we did above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Here we content ourselves with  the zeroth and first order terms in ℓ2 (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' in 1/m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' At  that level of approximation, (C11) yields the zeroth order  statement  V0 − E0  m = 0  (C12)  and the first-order result  f ′n  �  Λℓ2m[W0 −E1  m]+ H  2 + 3LG  4Λ  �  + G  2  �  In′ +Jn  �  = 0,  (C13)  where ℓ2m = O(1) as before.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (C12) confirms that the  eigenvalue equation holds if E0  m = V0(ℓ2m), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' if the en-  ergy of the eigenstate |ψm⟩ is that of its equipotential at  leading order [recall (9)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' More important, (C13) yields  a transport equation for n, whose schematic form is  GI  2  n′  n +f ′�  Λℓ2m(W0−E1  m)+ H  2 + 3LG  4Λ  �  + GJ  2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (C14)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='We now rely on the expansions (C5)–(C8) to write this  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='transport equation explicitly: using the notation (33) and  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='plugging (C5)–(C8) into (C3) yields the condition  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='0 =  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='dε e  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='− Kf ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1+ A2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='ε2 �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 + ε  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='A + f ′ n′(f)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='n(f)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�� �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 + Kf ′ε3 �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='6 − A  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4 − iB  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='12 + iA2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='8 − AB  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='8 + A3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='16  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='×  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='−iℓ2Kε  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 + A2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='Ωm − ℓ2Kε2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 + A2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='Γm + ℓ2Kε2 �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='− 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2 + B  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='8 − 3A2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='− A3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4i − A4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='16 + AB  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4i + A2B  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='32  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='Ωm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='+ ℓ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='f ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 − B  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4 + A2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='Ωm + ℓ2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='f ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='1 + A2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='Γm − ℓ2E1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='m  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=',' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (C15)  whose structure is that announced in (C11),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' as had to  be the case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' What remains is to multiply all the factors  in the integrand, keep track of powers of ε and integrate  over ε, which leads to  iR′/R =  �  1 + A2  4  �  Γm  2Ωm + 1 − B  4 + A2  2 − f ′ E1  m  Ωm  −  1  1 + A2  4  ��  B  8 + A4  16 − A2B  32  �  + i  �  A  4 + 3A3  16 − AB  8  ��  ,  (C16)  where we introduced R ≡ R(α) ≡ n(f(α)) for simplicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  This is the transport equation for the O(1) multiplica-  tive factor of the WKB ansatz (30).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Its real and imag-  inary parts, respectively, govern the phase and norm of  n(f(ϕ)) ≡ N(ϕ) eiΦ(ϕ):  −Φ′ =  �  1 + A2  4  �  Γm  2Ωm − f ′ E1  m  Ωm  +  1  1+ A2  4  �  1 + 3A2  4  + A4  16 − 3B  8 − A2B  32  �  , (C17)  N ′/N = −  1  1 + A2  4  �  A  4 + 3A3  16 − AB  8  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  (C18)  The identity B = A′+A2 then reduces these two relations  to Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (32) and (38) in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  19  [1] K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' von Klitzing, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Dorda, and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Pepper, New method  for high-accuracy determination of the fine-structure con-  stant based on quantized Hall resistance, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  45, 494 (1980).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  [2] D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Tsui, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Stormer, and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Gossard, Two-  dimensional magnetotransport in the extreme quantum  limit, Phys, Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 48, 1559 (1982).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  [3] R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Laughlin, Anomalous quantum Hall effect: An in-  compressible quantum fluid with fractionally charged ex-  citations, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 50, 1395 (1983).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  [4] P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Delplace and G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Montambaux, WKB analysis of edge  states in graphene in a strong magnetic field, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  B 82, 205412 (2010), arXiv:1007.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='2910 [cond-mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='mes-  hall].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  [5] G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Montambaux, Semiclassical quantization of skipping  orbits, Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' B 79, 215 (2011), arXiv:1006.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='5819  [cond-mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='mes-hall].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content=' Lee and R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content='  Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' 57, 023302 (2016), arXiv:1501.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='02781 [math-  ph].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  [72] This is ‘harmonic’ in that it holds when V0(r2/2) =  Ω r2/2 in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' (25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content='  21  [73] One finds δ2 = ia2 �  2−{f(α),α}  4  − i f′′(α)  2f′(α)  �  1 − i f′′(α)  2f′(α)  ��  ×  �  1−i f′′(α)  2f′(α)  �−3  with the Schwarzian derivative {f(α), α}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Mod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content='  [75] Properly  normalized,  the  tangent  vector  is  �√  2ℓ/σ√f ′��  r−1∂ϕ + (f ′′/2f ′)∂r  �  for |r| = ℓ√2Nf ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' We  recall that dϕ · ∂ϕ = 1 = dr · ∂r and dϕ · ∂r = 0 = dϕ · ∂r  with ||∂ϕ|| = r = ||dϕ||−1 and ||∂r|| = 1 = ||dr||.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content='str-el].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content=' W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Moore and N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Read, Nonabelions in the fractional  quantum Hall effect, Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
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+page_content='  [95] Strictly speaking, the left-hand side of (C1) should be  O(ℓ4) since we already truncated the expansion of the  P V P operator to order O(ℓ2), but we just write it as  zero for simplicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/DtAzT4oBgHgl3EQfwv4v/content/2301.01726v1.pdf'}
diff --git a/GNE3T4oBgHgl3EQftgtb/content/tmp_files/2301.04676v1.pdf.txt b/GNE3T4oBgHgl3EQftgtb/content/tmp_files/2301.04676v1.pdf.txt
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@@ -0,0 +1,1889 @@
+CFTP/23-001
+A viable A4 3HDM theory of quark mass matrices
+Iris Brée∗, Sérgio Carrôlo †, Jorge C. Romão ‡, João P. Silva §,
+CFTP, Departamento de Física,
+Instituto Superior Técnico, Universidade de Lisboa,
+Avenida Rovisco Pais 1, 1049 Lisboa, Portugal
+January 13, 2023
+Abstract
+It is known that a three Higgs doublet model (3HDM) symmetric under an exact A4 sym-
+metry is not compatible with nonzero quark masses and/or non-block-diagonal CKM matrix.
+We show that a 3HDM with softly broken A4 terms in the scalar potential does allow for a
+fit of quark mass matrices. Moreover, the result is consistent with mh = 125GeV and the
+h → WW, ZZ signal. We also checked numerically that, for each point that passes all the
+constraints, the minimum is a global minimum of the potential.
+1
+Introduction
+The observation in 2012 of a scalar particle with 125GeV by the ATLAS and CMS collaborations
+[1, 2] has incentivized experimental searches for beyond the Standard Model (SM) particles at the
+LHC. On par with these experimental endeavors, theoretical efforts in the search for extra scalar
+particles have been strengthened since this discovery. A promising framework is found in N-Higgs
+doublet models (NHDM).
+Such models have many free parameters, which are often curtailed by imposing some discrete
+family symmetry. Here, we focus on the implementation of A4 in a three Higgs doublet model
+(3HDM). The A4 group is the group of even permutations on 4 elements.
+It is the smallest
+discrete group to contain a three-dimensional irreducible representation (irrep), which is ideal for
+describing the three families of quarks with a minimal number of independent Yukawa couplings.
+Thus, NHDM supplemented by the A4 discrete symmetry has long been of interest in flavour
+physics research.
+A number of early articles include: [3], mainly devoted to the leptonic sector and where the
+solution to the quark sector is briefly mentioned to include a fourth Higgs doublet and all quark
+fields in singlets (which is effectively the same as the Standard Model quark sector); [4], where A4
+is broken by dimension four Yukawa couplings, thus rendering the theory non-renormalizable or,
+alternatively, the low energy limit of a broader complete theory; [5], which requires three Higgs
+doublets in the down-type quark sector and a further two in the up-type quark sector, consisting
+∗iris.bree.silva@tecnico.ulisboa.pt
+†sergio.carrolo@tecnico.ulisboa.pt
+‡jorge.romao@tecnico.ulisboa.pt
+§jpsilva@cftp.ist.utl.pt
+1
+arXiv:2301.04676v1  [hep-ph]  11 Jan 2023
+
+of a 5HDM; and [6], which is devoted to the leptonic sector, but has the interesting side query
+that it might be possible to recover a realistic CKM matrix through soft-breaking of A4.
+Quark mass matrices in the context of a 3HDM with Higgs doublets in the triplet representation
+of A4 were studied in [7] and [8], with the vacuum expectation value (vev) structure (eiα, e−iα, r),
+where α and r are real constants. Unfortunately, Degee, Ivanov and Keus [9] proved in 2013 that
+such a vacuum can never be the global minimum of the A4 symmetric 3HDM. In this beautiful
+paper, geometric techniques were used in order to identify all possible global minima (thus, all
+possible viable vacua) of the A4 symmetric 3HDM. Immediately thereafter, those minima were
+used to show that all assignments of the quark fields into irreps of A4, when combined with the
+possible vevs for the exact A4 potential, yield vanishing quark masses and/or a CP conserving
+CKM matrix, both of which are forbidden by experiment. This is in fact a consequence of a much
+broader theorem, proved in [10, 11]: given any flavour symmetry group, one can obtain a physical
+CKM mixing matrix and, simultaneously, non-degenerate and non-zero quark masses only if the
+vevs of the Higgs fields break completely the full flavour group. The idea is that a symmetry will
+reduce the number of redundant Yukawa couplings present in the SM, and it might even predict
+relations among observables which turn out to be consistent with experiment.
+When studying in detail the extensions of A4 to the quark sector found by Ref. [12], we noticed
+that, in some of them, if it weren’t for the particular form of the vevs allowed by the exact A4
+3HDM potential, the Yukawa matrices could allow for massive quarks, and for a realistic CKM
+matrix. Since the A4 symmetric potential doesn’t allow for minima other than those shown in [9],
+here we consider the case where the A4 symmetry is softly broken by the addition of quadratic
+terms to the potential. Such terms do not spoil the theory’s renormalizability, but break the A4
+symmetry.
+Our article is organized as follows. We define the notation for the scalar potential in Sec. 2.1,
+discuss the Yukawa Lagrangian and the form of the possible mass matrices in Sec. 2.2, giving all
+the expressions needed for the fit in Sec. 2.3. In Sec. 3 we present our fit to the quarks mass
+matrices, while in Sec. 4 we discuss the viability of the vacuum found in the fit in terms of the
+scalar potential.
+Sec. 5 is devoted to the implementation of the theoretical constraints to be
+imposed, and in Sec. 6 we briefly discuss the constraints coming from the LHC. The results and
+conclusions are presented in Sec. 7 and 8, respectively. The Appendices contain some additional
+expressions that are needed for the fits.
+2
+Parameterization for the softly-broken A4 3HDM
+2.1
+Potential and candidates for local minimum
+The softly-broken potential of the 3HDM with an A4 symmetry is given by
+VH = V4, A4 + M2
+ij
+�
+φ†
+iφj
+�
+,
+(1)
+where V4, A4 is the quartic potential for the A4 symmetric three Higgs doublet model (3HDM),
+which is, in the notation of [9],
+2
+
+V4, A4 =Λ0
+3
+�
+φ†
+1φ1 + φ†
+2φ2 + φ†
+3φ3
+�2
++ Λ1
+��
+Re
+�
+φ†
+1φ2
+��2 +
+�
+Re
+�
+φ†
+2φ3
+��2 +
+�
+Re
+�
+φ†
+3φ1
+��2�
++ Λ2
+��
+Im
+�
+φ†
+1φ2
+��2 +
+�
+Im
+�
+φ†
+2φ3
+��2 +
+�
+Im
+�
+φ†
+3φ1
+��2�
++ Λ3
+3
+�
+(φ†
+1φ1)2 + (φ†
+2φ2)2 + (φ†
+3φ3)2 − (φ†
+1φ1)(φ†
+2φ2) − (φ†
+2φ2)(φ†
+3φ3) − (φ†
+3φ3)(φ†
+1φ1)
+�
++ Λ4
+�
+Re
+�
+φ†
+1φ2
+�
+Im
+�
+φ†
+1φ2
+�
++ Re
+�
+φ†
+2φ3
+�
+Im
+�
+φ†
+2φ3
+�
++ Re
+�
+φ†
+3φ1
+�
+Im
+�
+φ†
+3φ1
+��
+.
+(2)
+The matrix M2
+ij is a general hermitian matrix, which can be parameterized by
+(M2
+ij) =
+�
+�
+�
+m2
+11
+m2
+12eiθ12
+m2
+13eiθ13
+m2
+12e−iθ12
+m2
+22
+m2
+23eiθ23
+m2
+13e−iθ13
+m2
+23e−iθ23
+m2
+33
+�
+�
+� ,
+(3)
+where m2
+ij are real parameters with the dimension of mass squared.1
+Additionally, in the notation of [13], the exact A4 potential can be written as
+VA4 =r1 + 2r4
+3
+�
+(φ†
+1φ1) + (φ†
+2φ2) + (φ†
+3φ3)
+�2 + 2(r1 − r4)
+3
+�
+(φ†
+1φ1)2 + (φ†
+2φ2)2
++(φ†
+3φ3)2 − (φ†
+1φ1)(φ†
+2φ2) − (φ†
+2φ2)(φ†
+3φ3) − (φ†
+3φ3)(φ†
+1φ1)
+�
++ 2r7
+�
+|φ†
+1φ2|2 + |φ†
+2φ3|2 + |φ†
+3φ1|2�
++
+�
+c3
+�
+(φ†
+1φ2)2 + (φ†
+2φ3)2 + (φ†
+3φ1)2�
++ h.c.
+�
+.
+(4)
+The relation between the two notations is
+r1 = 1
+3(Λ0 + Λ3) ,
+r4 = 1
+6(2Λ0 − Λ3) ,
+r7 = 1
+4(Λ1 + Λ2) ,
+Re(c3) = 1
+4(Λ1 − Λ2) ,
+Im(c3) = −1
+4Λ4 .
+(5)
+We consider that the scalar fields can take complex vacuum expectation values (vevs), to be
+determined later. Thus, we write,
+φi =
+�
+ϕ+
+i
+|vi|eiρi
+√
+2
++
+1
+√
+2 (xi + ixi+3)
+�
+.
+(6)
+Because CP is spontaneously violated, the unrotated neutral fields have no definite CP, and for
+convenience we label them xi, i = 1, . . . , 6. We can also use the gauge freedom to absorb one of
+the phases in the vevs, that we choose to be ρ1. Therefore we have the vector of vevs defined as
+⃗v = (|v1|, |v2|eiρ2, |v3|eiρ3) .
+(7)
+1In the quadratic terms, the combination − M0
+√
+3
+�
+φ†
+1φ1 + φ†
+2φ2 + φ†
+3φ3
+�
+is also invariant under A4. But, since we
+are keeping all soft-breaking terms, we find the notation in (3) more convenient.
+3
+
+This vev contributes with four free parameters to our model, because one of the parameters is
+constrained by the mass of the gauge bosons to match the observed SM values,
+|v1|2 + |v2|2 + |v3|2 ≡ v2 ≃ (246GeV)2.
+(8)
+The vev can also be parameterised as
+⃗v = v
+�
+cos(β1) cos(β2), cos(β2) sin(β1)eip2, sin(β2)eip3�
+.
+(9)
+Of the quantities arising out of the scalar potential, the vevs are the only relevant to the quark
+mass matrices. This leads many authors to just proclaim some vevs, without checking whether
+they can indeed be the global minima of a realistic Higgs potential. We will perform this crucial
+verification below, in Section 4.
+2.2
+Yukawa Lagrangian
+As in Refs. [7, 12], we consider that the Higgs doublets are in the 3 of A4 as well as the three
+left-handed SU(2) doublets QLj of hypercharge 1/6. There are three right-handed SU(2) singlets
+nR,j of hypercharge −1/3 and three right-handed SU(2) singlets pR,j of hypercharge 2/3. Our
+assignments for the singlets are as follows
+nR1, pR1 → 1,
+nR2, pR2 → 1′,
+nR3, pR3 → 1′′ of A4 .
+(10)
+Then, the A4 transformations on the fields are generated by [7, 12]
+T :
+�
+�
+�
+�
+�
+�
+�
+�
+�
+�
+�
+φ1 → φ2 → φ3 → φ1,
+QL1 → QL2 → QL3 → QL1,
+nR1 → nR1, nR2 → ωnR2, nR3 → ω2nR3,
+pR1 → nR1, pR2 → ωpR2, pR3 → ω2pR3,
+(11)
+and
+S :
+�φ1 → φ1, φ2 → −φ2, φ3 → −φ3,
+QL1 → QL1, QL2 → −QL2, QL3 → −QL3.
+(12)
+One can easily verify that the scalar potential in Eq. (4) is invariant under the previous transfor-
+mations. Now we write the A4 invariant Yukawa Lagrangian for quarks. We have
+−LYukawa =
+√
+2 ˆa
+�
+QL1φ1 + QL2φ2 + QL3φ3
+�
+nR1
++
+√
+2ˆb
+�
+QL1φ1 + ω QL2φ2 + ω2 QL3φ3
+�
+nR2
++
+√
+2 ˆc
+�
+QL1φ1 + ω2 QL2φ2 + ω QL3φ3
+�
+nR3
++
+√
+2 ˆa′ �
+QL1 ˜φ1 + QL2 ˜φ2 + QL3 ˜φ3
+�
+pR1
++
+√
+2ˆb′ �
+QL1 ˜φ1 + ω QL2 ˜φ2 + ω2 QL3 ˜φ3
+�
+pR2
++
+√
+2 ˆc′ �
+QL1 ˜φ1 + ω2 QL2 ˜φ2 + ω QL3 ˜φ3
+�
+pR3 + h.c.,
+(13)
+4
+
+where, as usual,
+˜φj ≡ i σ2φ∗
+j ,
+(14)
+and we define
+ˆa = aei α, ˆb = bei β, ˆc = cei γ, ˆa′ = a′ei α′, ˆb′ = b′ei β′, ˆc′ = c′ei γ′ ,
+(15)
+where a, b, c, a′, b′, c′ are real and positive. This choice of invariant Lagrangian corresponds to the
+case I identified in Ref. [12] (see the next section).
+2.3
+Yukawa matrices, masses and CKM
+We aim to fit six quark masses and four CKM matrix elements to the currently accepted SM
+values for these observables. Therefore, we’re interested in softly-broken A4 symmetric models
+with up to ten parameters. Ref. [12] has studied all of the possible extensions of A4 to the fermion
+sector. Using their results, we can check which of them can accommodate non-vanishing quark
+masses, CKM mixing angles and CP violation by considering a general vev ⃗v. We take the Jarlskog
+invariant as a measure of CP violation [14]. Out of all possibilities, we are left with five of them,
+which we list in Table 1. There, A are real constants, Ω are constants in the [0, 2π[ interval,
+ω = ei 2π
+3 (ω3 = 1) and T is the transpose of the matrix.
+Case
+Md
+Mu
+I
+�
+�
+�
+aeiαv1
+beiβv1
+ceiγv1
+aeiαv2
+ωbeiβv2
+ω2ceiγv2
+aeiαv3
+ω2beiβv3
+ωceiγv3
+�
+�
+�
+�
+�
+�
+A → A′,
+A ∈ {a, b, c}
+Ω → Ω′,
+Ω ∈ {α, β, γ}
+vi → v∗
+i ,
+i ∈ {1, 2, 3}
+�
+�
+�
+II
+IT
+d
+IT
+u
+III
+�
+�
+�
+0
+(aeiα − beiβ)v3
+(aeiα + beiβ)v2
+(aeiα + beiβ)v3
+0
+(aeiα − beiβ)v1
+(aeiα − beiβ)v2
+(aeiα + beiβ)v1
+0
+�
+�
+�
+�
+�
+�
+A → A′,
+A ∈ {a, b}
+Ω → Ω′,
+Ω ∈ {α, β}
+vi → v∗
+i ,
+i ∈ {1, 2, 3}
+�
+�
+�
+IV
+Id
+IIIu
+V
+IIId
+Iu
+Table 1: Extensions of A4 to the Yukawa sector with non-vanishing determinant, and non-zero J
+for general, complex valued, vevs (v1, v2, v3). In the Table, Id stands for the matrix Md for case I
+and similarly for the other entries.
+In the Yukawa sector, there are ten observables, six masses, three mixing angles and one
+Jarlskog invariant, therefore, we would prefer to look for a case with ten parameters, or less. All
+possible neutral vevs of the 3HDM are consistent with the parameterization in Eq. (9), which
+consists of four free parameters that we can fit; two angles, and two phases. Looking at the cases
+in Table 1, we will see that it is possible to reduce the number of free parameters by performing
+both basis transformations to right-handed quarks and global U(1)Y rephasings, both of which
+have no effect on the physical predictions of the theory.
+For case I, the down quark mass matrices read
+5
+
+Md =
+�
+�
+�
+aeiαv1
+beiβv1
+ceiγv1
+aeiαv2
+ωbeiβv2
+ω2ceiγv2
+aeiαv3
+ω2beiβv3
+ωceiγv3
+�
+�
+� = DvWDaDα,
+(16)
+where (remember that the vi are complex)
+Dv = diag(v1, v2, v3) , Da = diag(a, b, c) , Dα = diag(eiα, eiβ, eiγ) , W =
+�
+�
+�
+1
+1
+1
+1
+ω
+ω2
+1
+ω2
+ω
+�
+�
+� .
+(17)
+We see that we can perform a unitary transformation to the right-handed quarks that removes all
+three phases α, β, γ. The same holds for Mu, by performing the substitution A → A′, Ω → Ω′
+and vi → v∗
+i .
+For case II, the quark mass matrices have the form
+Md = DaDαWDv and Mu = Da′Dα′WDv∗ .
+(18)
+Thus, we can remove the phases of the vev through an appropriate transformation of the right-
+handed quarks, but we can only remove α through a global rephasing QL → Q′
+L = eiαQL of
+the left-handed quarks. This rephasing, however, doesn’t remove the phase α′ in the matrix Mu,
+because, in general, it will be different from α. Now, for case III, we can only remove α and
+α′ 2 by performing the corresponding rephasings of the right-handed quarks. Finally, for the case
+IV (V), we can remove, as we did for case I, all the phases from the Yukawa couplings α, β, γ
+(corresponding primes), and only one phase α′ (corresponding unprimed). To summarise, we can
+classify the cases above according to their number of free-parameters, which we show in the Table
+below.
+case
+#θ
+#p
+#A
+#α
+#A′
+α′
+Total
+I
+2
+2
+3
+3 − 3 = 0
+3
+3 − 3 = 0
+10
+II
+2
+2 − 2 = 0
+3
+3 − 1 = 2
+3
+3
+13
+III
+2
+2
+2
+2 − 1 = 1
+2
+2 − 1 = 1
+10
+IV
+2
+2
+3
+3 − 3 = 0
+2
+2 − 1 = 1
+10
+V
+2
+2
+2
+2 − 1 = 1
+3
+3 − 3 = 0
+10
+Table 2: Number of parameters for each case of Table 1. θ and p are the angles and phases of the
+vev, A(A′) are the Yukawa couplings of the down (up) quarks, and α(α′) are the Yukawa phases
+of the down (up) quarks. The minus signs correspond to the parameters that we can remove by
+a basis transformation of the quark sector.
+In this work, we study case I, that corresponds to the Lagrangian in Eq. (13). Then, given
+that DαD†
+α = 1 and DaD†
+a = Da2 = diag(a2, b2, c2), we find
+Hd
+≡
+MdM†
+d = DvSdD†
+v ,
+Hu
+≡
+MuM†
+u = D†
+vSuDv ,
+(19)
+2We could have chosen to remove β and β′ instead, this is just one possible choice.
+6
+
+where Sd = WDa2W † and a2 → a′2 for the up quark case. This matrix can now be explicitly
+written out using appropriate parameters as
+Sd =
+�
+�
+�
+Σd
+Zdeiφd
+Zde−iφd
+Zde−iφd
+Σd
+Zdeiφd
+Zdeiφd
+Zde−iφd
+Σd
+�
+�
+� ,
+(20)
+where Σd and Zd are real, and
+Σd
+≡
+a2 + b2 + c2 ,
+Zd eiφd
+≡
+a2 + ω2b2 + ωc2 ,
+(21)
+with corresponding primes for the up case.
+For completeness, the specific forms for Hd and
+Hu found after using the parameterizations in Eqs. (9) and (21) are written in Appendix A.
+The eigenvalues of the matrices Hd and Hu will be fitted for the (square of the) quark masses,
+(m2
+d, m2
+s, m2
+b) and (m2
+u, m2
+c, m2
+t ), respectively
+We now turn to the Cabibbo-Kobayashi-Maskawa (CKM) matrix. As found by Branco and
+Lavoura [15], the absolute values of the CKM matrix can be obtained through calculating the
+traces of appropriate powers of the matrices Hu and Hd. They observe that
+Tr
+�
+Ha
+uHb
+d
+�
+≡ Lab =
+�
+k,i
+Uki(Da
+u)kk(Db
+d)ii ,
+(22)
+where Uki = |Vki|2 and V is the CKM matrix. The CKM matrix is unitary and therefore U only
+has four independent entries. Consequently, in order to compute U, it is only necessary to resort
+to
+L11 =Uki(Du)kk(Dd)ii ,
+L12 =Uki(Du)kk(D2
+d)ii ,
+L21 =Uki(D2
+u)kk(Dd)ii ,
+L22 =Uki(D2
+u)kk(D2
+d)ii .
+(23)
+These equations are linear in Uik and are, therefore, invertible for this variable. Thus, by picking
+U11, U21, U13, and U23 (respectively, Uud, Ucd, Uub, and Ucb), we are able to obtain a unique
+solution for the magnitudes of the CKM elements as a function of Lab and the quark masses.
+Namely,
+U11
+=
+�
+mb2 − ms2� �
+mc2 − mt2� a11
+det ,
+U21
+=
+�
+mb2 − ms2� �
+mu2 − mt2� a21
+det ,
+U13
+=
+�
+md2 − ms2� �
+mc2 − mt2� a13
+det ,
+U23
+=
+�
+md2 − ms2� �
+mu2 − mt2� a23
+det ,
+(24)
+where
+a11
+=
+L11
+�
+mb2 + ms2� �
+mc2 + mt2�
+− L12
+�
+mc2 + mt2�
+− L21
+�
+mb2 + ms2�
++ L22
+7
+
++m2
+b
+�
+−m2
+cm2
+t
+�
+m2
+d + m2
+s
+�
+− m2
+sm2
+u
+�
+m2
+c + m2
+t
+�
++ m2
+sm4
+u
+�
++ m2
+cm2
+dm2
+t
+�
+m2
+d − m2
+s
+�
+,(25)
+a21
+=
+−L11
+�
+mb2 + ms2� �
+mt2 + mu2�
++ L12
+�
+mu2 + mt2�
++ L21
+�
+mb2 + ms2�
+− L22
++m2
+b
+�
+m2
+cm2
+s
+�
+m2
+t + m2
+u − m2
+c
+�
++ m2
+t m2
+u
+�
+m2
+d + m2
+s
+��
++ m2
+dm2
+t m2
+u
+�
+m2
+s − m2
+d
+�
+,
+(26)
+a13
+=
+−L11
+�
+md2 + ms2� �
+mt2 + mc2�
++ L12
+�
+mc2 + mt2�
++ L21
+�
+md2 + ms2�
+− L22
++m2
+bm2
+cm2
+t
+�
+m2
+d + m2
+s − m2
+b
+�
++ m2
+dm2
+s
+�
+m2
+c
+�
+m2
+t + m2
+u
+�
++ m2
+u
+�
+m2
+t − mu2��
+,
+(27)
+a23
+=
+L11
+�
+md2 + ms2� �
+mt2 + mu2�
+− L12
+�
+mu2 + mt2�
+− L21
+�
+md2 + ms2�
++ L22
++m2
+t m2
+u
+�
+m4
+b − m2
+b
+�
+m2
+d + m2
+s
+�
+− m2
+dm2
+s
+�
++ m4
+cm2
+dm2
+s − m2
+cm2
+dm2
+s
+�
+m2
+t + m2
+u
+�
+,
+(28)
+and
+det =
+�
+mb2 − md2� �
+mc2 − mu2� �
+md2 − ms2� �
+mu2 − mt2� �
+mb2 − ms2� �
+mc2 − mt2�
+.
+(29)
+In these equations, the Lij are obtained by evaluating the left hand side of Eq. (22). Finally, we
+note that knowing these four CKM magnitudes, we can determine the Jarslkog invariant [14], up
+to its sign. Thus, given some phase convention, we are also able to determine the phases of all
+CKM matrix elements.
+3
+The fit to the quark mass matrices
+3.1
+The fitting procedure
+We have implemented a χ2 analysis of the model, through a minimization performed using the
+CERN Minuit library [16]. The observables employed in this analysis, labeled by i = 1, ..., 11 are
+specified in Table 3, where Xi represents the experimental mean value of the observable Xi and
+σi is the experimental error, which, when both left and right bounds are stated, is assumed to be
+the largest of the two. The data on the quark masses as well as for the CKM matrix elements and
+Observable
+Experimental value
+Model prediction
+mu [MeV]
+2.16 ± 0.50
+2.15
+mc [MeV]
+1270 ± 20
+1271.9
+mt [GeV]
+172.69 ± 0.30
+172.69
+md [MeV]
+4.67 ± 0.50
+4.66
+ms [MeV]
+93.4 ± 8.6
+92.08
+mb [MeV]
+4180 ± 30
+4179.74
+|V11|
+0.97435 ± 0.00016
+0.97434
+|V21|
+0.22486 ± 0.00067
+0.22479
+|V13|
+0.00369 ± 0.00011
+0.00369
+|V23|
+0.04182 ± 0.00085
+0.04175
+J
+(3.08 ± 0.15) × 10−5
+3.09 × 10−5
+Table 3: Experimental values and fit results.
+the Jarlskog invariant experimental values were obtained from [17]. As mentioned, |J| is fixed by
+|V11|, |V21|, |V13|, and |V23|. However, using it in the fit speeds the numerical convergence onto a
+good solution.
+8
+
+The χ2 function depends on the 10 parameters of our model,
+β1, β2, ρ2, ρ3, Σd, Σu, Zd, Zu, φd, φu
+(30)
+and is written as
+χ2(p) =
+11
+�
+i=1
+�
+Pi(p) − Xi
+σi
+�2
+,
+(31)
+where Pi(p) is our model’s prediction for each of the 11 (10 + J) observables. The fit is complicated
+by the fact that the masses (squared) are obtained from the eigenvalues of Hd, Hu but the elements
+of the CKM also depend on the masses, see Eq. (24). So, we start by calculating the eigenvalues
+of Hd and Hu, which depend only on the parameters in Eq. (30). Then, we evaluate the Lij
+from the left hand side of Eq. (22), and finally the CKM elements are obtained from Eq. (24). In
+Appendix A we give the explicit expressions for the matrices Hd and Hu.
+3.2
+Results of the fit
+We have found an excellent fit of our model to the data, given in the second column of Table 3.
+This fit results in χ2 = 0.058, for the parameters
+β1 =1.42608 radians ,
+β2 =1.54243 radians ,
+ρ2 =4.27865 radians ,
+ρ3 =5.37039 radians ,
+Σd =0.288824 × 10−3 ,
+Σu =0.492828 ,
+Zd =0.181571 × 10−3 ,
+Zu =0.475911 ,
+φd = − 1.73226 radians ,
+φu =0.206453 × 10−3 radians .
+(32)
+This fit also leads to the data in the third column of Table 3, as well as to the vevs
+|vi| = (1.00625, 6.90462, 245.901) (GeV).
+(33)
+We notice that the vevs obey v1 < v2 << v3. This hierarchy of vevs is related to the hierarchy of
+the quark masses. This was also obtained in Ref. [7], although their model is not consistent, as
+their vev structure is not that of [9] for the symmetric A4 potential they consider.
+4
+Viability of the vacuum found in the fit
+We start by defining the three doublets as in Eq. (6). Next we define the physical eigenstates for
+the charged Higgs as (G+, S+
+2 , S2
+3)T , and for the neutral states we have (G0, S0
+2, S0
+3, S0
+4, S0
+5, S0
+6)T ,
+identifying the would-be Goldstone bosons G+ ≡ S+
+1 and G0 ≡ S0
+1. With these conventions, and
+following the definitions in [18], we define the 3 × 3 matrix ˜U by
+ϕ+
+i ≡
+3
+�
+j=1
+˜UijS+
+j ,
+(34)
+9
+
+and the 3 × 6 matrix ˜V by
+xi + ixi+3 =
+6
+�
+j=1
+˜VijS0
+j .
+(35)
+These matrices3 are then related to the diagonalization matrices of the charged and neutral scalars,
+to which we now turn.
+4.1
+The minimization of the potential
+In our procedure we already know the values of the vevs. So, we use the stationarity equations
+to solve for the soft parameters, and leave the quartic parameters of the potential Λi as free
+parameters. In this way we can solve for m2
+11, m2
+22, m2
+33 as well as for Im(m2
+12), Im(m2
+13), leaving
+as free parameters the Λi and Re(m2
+12), Re(m2
+13), Re(m2
+23), Im(m2
+23). When evaluating the scalar
+mass matrices (see below) the conditions have to be applied to ensure that we are at the minimum.
+For completeness we write these conditions in Appendix B.
+4.2
+The charged mass matrix
+The charged mass matrix is obtained from the second derivatives at the minimum,
+M2
+C =
+∂2VH
+∂ϕ+
+i ∂ϕ−
+j
+�����
+Min
+.
+(36)
+The matrix M2
+C is an hermitian matrix, with real eigenvalues and satisfying, with our usual
+conventions,
+RchM2
+CR†
+ch = diag(0, m2
+S+
+2 , m2
+S+
+3 ) ≡ M2
+Dch ,
+(37)
+where Rch is an unitary matrix that satisfies,
+S+
+i =
+3
+�
+j=1
+(Rch)ij ϕ+
+j .
+(38)
+This can be seen from
+Lmass = − ϕ−
+i
+�
+M2
+C
+�
+ij ϕ+
+j = −ϕ−
+i
+�
+R†
+chRchM2
+CR†
+chRch
+�
+ij ϕ+
+j = −ϕ−
+i
+�
+R†
+chM2
+DchRch
+�
+ij ϕ+
+j
+= − S−
+i
+�
+M2
+Dch
+�
+ij S+
+j ,
+(39)
+where we have used Eq. (38).
+We have checked both algebraically and numerically that we have a zero eigenvalue corre-
+sponding to G+ and we require that all other masses squared are positive, a condition for a local
+minimum.
+3From the point of view of a simultaneous fit of the Yukawa and scalar sectors, it is a pity that these matrices
+˜V and ˜U have in the literature the same notation as the CKM matrix V and Uki = |Vki|2.
+10
+
+4.3
+The neutral mass matrix
+Since in our case CP is not conserved, we denote the unrotated neutral scalars by xi, i = 1, . . . , 6,
+as in Eq. (6). We therefore obtain the neutral mass matrix as,
+M2
+N =
+∂2VH
+∂xi∂xj
+�����
+Min
+.
+(40)
+This is a symmetric real matrix diagonalized by an orthogonal 6 × 6 matrix,
+RneuM2
+NRT
+neu = diag(0, m2
+S0
+2, m2
+S0
+3, m2
+S0
+4, m2
+S0
+5, m2
+S0
+6) ≡ M2
+Dneu ,
+(41)
+with
+S0
+i =
+6
+�
+j=1
+(Rneu)ij xj .
+(42)
+As for the case of the charged scalars, we have checked both algebraically and numerically that
+we have a zero eigenvalue corresponding to G0 and we require that all other masses squared are
+positive, a condition for a local minimum.
+5
+Theoretical Constraints
+After having shown that a solution exists for the vevs and parameters in the Yukawa sector that
+correctly fits the quarks masses and the CKM entries, we have to show that this is compatible
+with the scalar potential analysis. In particular we have to show that the vevs correspond to a
+local minimum of the potential and that both the theoretical constraints as well as those coming
+from LHC are satisfied. In this section we analyze the theoretical constraints.
+5.1
+Perturbative Unitarity
+This problem was already solved in [13], so we take the potential in the form of Eq. (4). From
+Ref. [13] we have the following expression for the eigenvalues λi4
+λ1 =2 (2Re(c3) + r1)
+(43)
+λ2 =2
+�√
+3 |Im(c3)| − Re(c3) + r1
+�
+(44)
+λ3 =2
+�
+−
+√
+3 |Im(c3)| − Re(c3) + r1
+�
+(45)
+λ4 =2(r4 + r7)
+(46)
+λ5 =2(r4 − r7)
+(47)
+λ6 =2(r1 + 2r7)
+(48)
+λ7 =2(r1 − r7)
+(49)
+λ8 =2(r4 + |c3|)
+(50)
+λ9 =2(r4 − |c3|)
+(51)
+λ10 =6r1 + 8r4 + 4r7
+(52)
+λ11 =6r1 − 2(2r4 + r7)
+(53)
+λ12 =6|c3| + 2r4 + 4r7
+(54)
+4We use λi instead of Λi, in order to not confuse with the notation of Eq. (2).
+11
+
+λ13 = − 6|c3| + 2r4 + 4r7
+(55)
+Perturbative unitarity is satisfied if
+|λi| < 8π,
+∀i.
+(56)
+5.2
+The BFB conditions
+For the A4 symmetric potential, the conditions for boundedness from below along the neutral
+directions (BFB-n) have been conjectured in [19], and proved to hold in [20]. These are
+Λ0 + Λ3 ≥ 0 ,
+(57)
+4
+3(Λ0 + Λ3) + 1
+2(Λ1 + Λ2) − Λ3 − 1
+2
+�
+(Λ1 − Λ2)2 + Λ2
+4 ≥ 0 ,
+(58)
+Λ0 + 1
+2(Λ1 + Λ2) + 1
+2(Λ1 − Λ2) cos (2kπ/3) + 1
+2Λ4 sin (2kπ/3) ≥ 0
+(k = 1, 2, 3) .
+(59)
+However, as shown in [21, 19], a potential which is BFB-n is not necessarily BFB along the
+charge breaking directions (BFB-c). Necessary BFB-c conditions have yet to be found for the A4
+3HDM, but sufficient conditions have been proposed in [22] following the technique developed in
+[23]. They are,
+Ad ≥ 0 ,
+Ao ≥ −Ad/2 ,
+(60)
+where
+Ad =a = 2
+3(Λ0 + Λ3) ,
+Ao =b + min(0, c) − d
+=1
+3(2Λ0 − Λ3) + 1
+2(Λ1 + Λ2) + min(0, −1
+2(Λ1 + Λ2)) − 1
+2
+�
+(Λ1 − Λ2)2 + Λ2
+4 .
+(61)
+It is important to remark that, since these are sufficient, but not necessary, conditions, some
+good points in parameter space may be excluded by this restriction.
+5.3
+The oblique parameters S, T, U
+For this we use the notation and results from [18], which require the matrices ˜U and ˜V . Comparing
+Eq. (38) with the definition in Eq. (34), we conclude that
+˜U = R†
+ch ,
+(62)
+where the matrix Rch is obtained from the numerical diagonalization of Eq. (37).
+Similarly,
+comparing Eq. (42) with the definition of ˜V in Eq. (35), we get,
+˜Vij =
+�
+RT
+neu
+�
+ij + i
+�
+RT
+neu
+�
+i+3,j .
+(63)
+Having ˜U and ˜V , we can construct the needed matrices Im
+� ˜V † ˜V
+�
+, ˜U† ˜U, ˜V † ˜V and ˜U† ˜V , and
+implement the procedure of [18].
+12
+
+5.4
+Global minimum
+After finding a set of mi,j and Λi which reproduce the vevs in Eq. (33) necessary for a good fit
+of the quark mass matrices, and after performing the previous theoretical checks on the scalar
+potential, we must still ensure that our minimum is indeed the global minimum. This step is
+almost never taken in studies of quark mass matrices, since there are no exact analytical formulae
+for it. Moreover, one must check that there are no lower minima both along the neutral directions
+and along the charge breaking directions. We follow the strategy discussed in Ref. [22]. Take a
+specific set of m2
+ij and Λi. Then we parameterize the scalar doublets as [21, 22],
+⟨φ1⟩ = √r1
+�
+0
+1
+�
+,
+⟨φ2⟩ = √r2
+�
+sin(α2)
+cos(α2)eiβ2
+�
+,
+⟨φ3⟩ = √r3eiγ
+�
+sin(α3)
+cos(α3)eiβ3
+�
+,
+(64)
+where we have already used the gauge freedom. Now we let the vevs run free, for both charge
+conserving and charge violating directions. We give one seed point and perform a minimization of
+the potential using the CERN Minuit library [16]. We obtain not only the value of the potential
+at the minimum, but also the values of ri, α2, β2, α3, β3 and γ. Then, we take one more (randomly
+generated) seed point and repeat the minimization. Finally, we take the minimum as the global
+one if it is found as the global minimum in each of 200 searches with randomly generated seed
+points. We have done this verification for every point that passed all the constraints. In all cases,
+we found that the local minimum was also a global minimum. In particular we always found that
+sin(α2) = sin(α3) = 0,
+(65)
+showing that we do not have charged breaking directions5 and, comparing with Eq. (6), we verified
+numerically that,
+|vi|
+√
+2 = √ri,
+ei ρ2 = cos(α2) ei β2,
+ei ρ3 = cos(α3) ei (β3+γ) .
+(66)
+6
+Simple LHC Constraints
+Up to now we have implemented the theoretical constraints on the model. The next step is to
+implement the LHC constraints. To do this completely one would have to implement all the decays
+of the neutral and charged Higgs as well as their branching ratios. One would also have to worry
+about the electric dipole moments (EDM) and the flavour-changing neutral couplings (FCNC), as
+the model does not have a structure of couplings of the Higgs to the fermions that automatically
+ensures vanishing FCNC [24, 25, 26]. This lies beyond the scope of the present work. Nonetheless,
+we can implement easily the constraints that come from h → WW/ZZ in the κ formalism, where
+the deviation from the coupling of the SM Higgs boson to a pair of W’s (or Z’s) is measured by
+κV . In our model,
+κV = Rneu
+21 v1 + Rneu
+22 v2 cos(ρ2) + Rneu
+23 v3 cos(ρ3) + Rneu
+25 v2 sin(ρ2) + Rneu
+26 v3 sin(ρ3),
+(67)
+where Rneu is matrix defined in Eq. (41). We take the experimental constraint from ATLAS [27],
+κW = 1.0206 +0.05172
+−0.05087,
+κZ = 0.99 +0.06136
+−0.05214 .
+(68)
+5To cross check our numerical procedure we also considered points that violated the BFB conditions. And, indeed
+for these points, our algorithm showed that the potential was not BFB and could have charge breaking directions
+as well.
+13
+
+7
+Results
+In this section we present the results of the analysis of the scalar potential after imposing that we
+have a good solution for the fit of the quarks masses and CKM entries, as explained in Section 3.
+7.1
+Scanning strategy
+We start by imposing the vevs obtained in the fit.
+v1 = 1.00625 (GeV),
+v2 = 6.90462 ei 4.27865 (GeV),
+v3 = 245.901 ei 5.37039 (GeV).
+(69)
+Now we vary the free parameters of the potential in the following ranges,
+log10 |Λi| ∈ [−3, 1],
+log10 |Im(m2
+23)| ∈ [−1, 7]GeV2,
+log10 |Re(m2
+ij)| ∈ [−1, 7]GeV2,
+(70)
+where in the last equation we use
+m2
+ij ∈
+�
+m2
+12, m2
+13, m2
+23
+�
+.
+(71)
+We randomly scan as in Eq. (70), and then:
+1. Apply the theoretical constraints that only depend on the Λi, that is BFB and perturbative
+unitarity.
+2. Then obtain the eigenvalues for the charged and neutral scalars. Verify that all the masses
+squared are positive, and that we have a zero eigenvalue corresponding to the Goldstone
+bosons, G0 and G+.
+3. Verify the S, T and U oblique parameters.
+4. Apply the LHC constraint on κV .
+5. Check numerically that the vev is indeed a global minimum.
+7.2
+The scalar spectrum
+We found that there is a strong correlation in the scalar masses.
+If we denote the masses of
+the neutral scalars by (mG0 = 0, mS0
+2, mS0
+3, mS0
+4, mS0
+5, mS0
+6), and (mG+ = 0, mH+
+1 , mH+
+2 ) for the
+charged scalars, we find numerically that
+mS0
+3 ≃ mS0
+4 ≃ mH+
+1 ,
+mS0
+5 ≃ mS0
+6 ≃ mH+
+2 .
+(72)
+This is true even if we do not require mS0
+2 = 125 GeV, and specially true after implementing
+the constraints of perturbative unitarity, BFB and STU. But, as we want to reproduce the LHC
+results, we also required that [17]
+mS0
+2 = 125.25 ± 0.17
+GeV.
+(73)
+In the following figures we show the correlation among the masses. Included in red are the
+points generated before the theoretical cuts were applied, and in green the points remaining after
+the constraints were implemented.
+14
+
+Figure 1: Left panel: Relation between mS0
+3 and mS0
+4. Right panel: Relation between mS0
+3 and
+mH+
+1 . Color conventions: No cuts (red); with cuts (green)
+Figure 2: Left panel: Relation between mS0
+5 and mS0
+6. Right panel: Relation between mS0
+5 and
+mH+
+2 . Color conventions: No cuts (red); with cuts (green)
+15
+
+2000
+1500
+1000
+500
+0
+500
+1000
+1500
+2000
+ms (GeV)2000
+1500
+mHt (GeV)
+1000
+500
+0
+500
+1000
+1500
+2000
+ms (GeV)2000
+1500
+1000
+500
+0
+500
+1000
+1500
+2000
+msg (GeV)2000
+1500
+ (GeV)
+1000
+500
+0
+500
+1000
+1500
+2000
+msg (GeV)Figure 3: Left panel: Relation between mS0
+3 and mS0
+5. Right panel: Relation between mH+
+1 and
+mH+
+2 . Color conventions: No cuts (red); with cuts (green)
+7.3
+The κV constraint
+We can now implement the κV constraint on the model. In the following figures, in red are points
+without cuts, in green with cuts but no κV constraint, and finally in blue points remaining after
+this constraint is applied. We took the ATLAS result of Eq. (68) at 2σ. While the theoretical
+constraints cut around 99% of the points, the κV constraint only cuts 9% of the remaining points.
+In Fig. 4 we show the relation between κV and Λ0,4 for the three sets of points as discussed above.
+Figure 4: Left panel: Relation between κV and Λ0. Right panel: Relation between κV and Λ4.
+Color conventions: No cuts (red), with theoretical cuts (green), and after the κV constraint (blue).
+In fact it is not obvious from Fig. 4 that the κV constraint only cuts about 9% of the points.
+This is because there is a very large number of points with |κV | ≲ 1, even without theoretical
+cuts, and this is even more so after imposing the theoretical cuts. In this figure, we have 157810
+points in the green region, but from these 145074 are in the blue region. That is, after theoretical
+16
+
+2000
+1500
+1000
+500
+500
+1000
+1500
+2000
+ms (GeV)2000
+..
+1500
+ (GeV)
+1000
+H
+500
+500
+1000
+1500
+2000
+mHt (GeV)10
+5
+.5
+-10
+0
+0.2
+0.4
+0.6
+0.8
+[Ky]10
+4
+-5
+-10
+0
+0.2
+0.4
+0.6
+0.8
+[Kvlcuts, 91% of the points also satisfy the κV constraint. In Fig. 5 we show the relation between Λ0
+and Λ3,4 for the same sets of points.
+Figure 5: Left panel: Relation between Λ0 and Λ4. Right panel: Relation between Λ0 and Λ3
+Color conventions: No cuts (red), with theoretical cuts (green), and after the κV constraint (blue).
+We see that, while for (Λ0, Λ4) there is not much difference before and after the κV constraint,
+the same is not true for (Λ0, Λ3), where the constraints impose a linear relation between those
+two parameters.
+8
+Conclusions
+It is known that the 3HDM symmetric under an exact A4 symmetry is not compatible with non-
+zero quark masses and/or non-block-diagonal CKM matrix [12]. In this work, we studied a 3HDM
+with A4 softly broken. This allows us to evade the above result, by enlarging the structure of the
+possible vacua.
+We obtained an excellent fit of the quarks mass matrices, including the CP-violating Jarlskog
+invariant. This leads to a unique solution for the vevs. We showed that, with the solution for the
+vevs obtained from the fit, it is possible to have a local minimum of the potential. We enforce
+this by imposing that all squared masses are positive. As in our scheme the scalar masses are not
+input parameters, we have to restrict one of the neutral scalars to have the mass of the known
+Higgs boson.
+We have implemented the BFB, perturbative unitarity and the oblique parameters S, T, U
+theoretical constraints.
+From LHC, we have considered the observed Higgs mass and the κV
+constraint.6 After imposing the other constraints, we found that most of the points are close to
+the alignment required to respect the experimental κV constraint. We have discovered a strong
+correlation among the masses of the scalars, even before applying the theoretical constraints,
+especially for moderate to large scalar masses.
+One important point is that we have numerically checked for all the points that pass our
+constraints, that for a given set of parameters of the potential, our minimum is the true global
+minimum.
+6The detailed study of other LHC constraints as well as those coming from FCNC and the EDM lies beyond the
+scope of the present work, and is left for a future publication.
+17
+
+0.6
+0.4
+0.2
+0
+0
+0.2
+0.4
+0.6
+No0.4
+0.2
+2
+0
+-0.2
+-0.4
+0
+0.1
+0.2
+0.3
+0.4
+NoAcknowledgments
+This work is supported in part by FCT (Fundação para a Ciência e Tecnologia) under Contracts
+CERN/FIS-PAR/0002/2021, CERN/FIS-PAR/0008/2019, UIDB/00777/2020, and UIDP/00777/2020;
+these projects are partially funded through POCTI (FEDER), COMPETE, QREN, and the EU.
+The work of I.B. was supported by a CFTP fellowship with reference BL210/2022-IST-ID and the
+work of S. C. by a CFTP fellowship with reference BL255/2022-IST-ID.
+A
+The matrices Hd and Hu
+Hd(1, 1) =Σdv2 cos2(β1) cos2(β2)
+(74)
+Hd(1, 2) =v2Zd cos(β1) cos2(β2) cos(ρ2 − φd) sin(β1)
+− i v2Zd cos(β1) cos2(β2) sin(β1) sin(ρ2 − φd)
+(75)
+Hd(1, 3) =v2Zd cos(β1) cos(β2) cos(ρ3 + φd) sin(β2)
+− i v2Zd cos(β1) cos(β2) sin(β2) sin(ρ3 + φd)
+(76)
+Hd(2, 1) =(Hd(1, 2))∗
+(77)
+Hd(2, 2) =Σdv2 cos2(β2) sin2(β1)
+(78)
+Hd(2, 3) =v2Zd cos(β2) cos(ρ2 − ρ3 + φd) sin(β1) sin(β2)
++ i v2Zd cos(β2) sin(β1) sin(β2) sin(ρ2 − ρ3 + φd)
+(79)
+Hd(3, 1) =(Hd(1, 3))∗
+(80)
+Hd(3, 2) =(Hd(2, 3))∗
+(81)
+Hd(3, 3) =Σdv2 sin2(β2)
+(82)
+Hu(1, 1) =Σuv2 cos2(β1) cos2(β2)
+(83)
+Hu(1, 2) =v2Zu cos(β1) cos2(β2) cos(ρ2 − φu) sin(β1)
+− i v2Zu cos(β1) cos2(β2) sin(β1) sin(ρ2 − φu)
+(84)
+Hu(1, 3) =v2Zu cos(β1) cos(β2) cos(ρ3 + φu) sin(β2)
+− i v2Zu cos(β1) cos(β2) sin(β2) sin(ρ3 + φu)
+(85)
+Hu(2, 1) =(Hu(1, 2))∗
+(86)
+Hu(2, 2) =Σuv2 cos2(β2) sin2(β1)
+(87)
+Hu(2, 3) =v2Zu cos(β2) cos(ρ2 − ρ3 + φu) sin(β1) sin(β2)
++ i v2Zu cos(β2) sin(β1) sin(β2) sin(ρ2 − ρ3 + φu)
+(88)
+Hu(3, 1) =(Hu(1, 3))∗
+(89)
+Hu(3, 2) =(Hu(2, 3))∗
+(90)
+Hu(3, 3) =Σuv2 sin2(β2)
+(91)
+B
+The minimization conditions
+m2
+11 = − sec(ρ2) sec(ρ3)
+24v2
+1
+�
+−12Im(m2
+23)v2v3 sin(2(ρ2 − ρ3)) + cos(ρ2 − ρ3)
+�
+4Λ0v2
+1v2
+18
+
++6Λ1v2
+1v2
+2 + 6Λ1v2
+1v2
+3 + 3Λ1v2
+2v2
+3 − 3Λ2v2
+2v2
+3 + 2Λ3v2
+1
+�
+2v2
+1 − v2
+2 − v2
+3
+��
++4Λ0v2
+1v2
+2 cos(ρ2 + ρ3) + 4Λ0v2
+1v2
+3 cos(ρ2 + ρ3) + 4Λ0v4
+1 cos(ρ2 + ρ3)
++6Λ1v2
+1v2
+2 cos(ρ2 + ρ3) + 6Λ1v2
+1v2
+3 cos(ρ2 + ρ3) − 3Λ1v2
+2v2
+3 cos(3(ρ2 − ρ3))
++3Λ2v2
+2v2
+3 cos(3(ρ2 − ρ3)) − 2Λ3v2
+1v2
+2 cos(ρ2 + ρ3) − 2Λ3v2
+1v2
+3 cos(ρ2 + ρ3)
++4Λ3v4
+1 cos(ρ2 + ρ3) + 3Λ4v2
+1v2
+2 sin(ρ2 − ρ3) + 3Λ4v2
+1v2
+2 sin(ρ2 + ρ3)
++3Λ4v2
+1v2
+3 sin(ρ2 − ρ3) − 3Λ4v2
+1v2
+3 sin(ρ2 + ρ3) − 3Λ4v2
+2v2
+3 sin(ρ2 − ρ3)
++3Λ4v2
+2v2
+3 sin(3(ρ2 − ρ3)) − 12Re(m2
+23)v2v3 cos(2(ρ2 − ρ3))
++24Re(m2
+13)v1v3 cos(ρ2) + 24Re(m2
+12)v1v2 cos(ρ3) + 12Re(m2
+23)v2v3
+�
+(92)
+m2
+22 = −
+1
+12v2
+�
+3 sec(ρ2)
+�
+−4Im(m2
+23)v3 sin(ρ3) + v2v2
+3(Λ1 − Λ2) cos(ρ2 − 2ρ3) − Λ4v2v2
+3 sin(ρ2 − 2ρ3)
++4Re(m2
+23)v3 cos(ρ3) + 4Re(m2
+12)v1
+�
++ v2
+�
+4Λ0v2 + 6Λ1v2
+1 + 3Λ1v2
+3 + 3Λ2v2
+3
+−2Λ3v2
+1 + 4Λ3v2
+2 − 2Λ3v2
+3 + 3Λ4v2
+1 tan(ρ2)
+� �
+(93)
+m2
+33 = −
+1
+12v3
+�
+3 sec(ρ3)
+�
+4Im(m2
+23)v2 sin(ρ2) + v2
+2v3(Λ1 − Λ2) cos(2ρ2 − ρ3) − Λ4v2
+2v3 sin(2ρ2 − ρ3)
++4Re(m2
+23)v2 cos(ρ2) + 4Re(m2
+13)v1
+�
++ v3
+�
+4Λ0
+�
+v2
+1 + v2
+2 + v2
+3
+�
++ 6Λ1v2
+1 + 3Λ1v2
+2
++3Λ2v2
+2 − 2Λ3v2
+1 − 2Λ3v2
+2 + 4Λ3v2
+3 − 3Λ4v2
+1 tan(ρ3)
+� �
+(94)
+Im(m2
+12) = 1
+4v1
+�
+sec(ρ2)
+�
+4Im(m2
+23)v3 cos(ρ2 − ρ3) − Λ1v2v2
+3 sin(2(ρ2 − ρ3)) − Λ1v2
+1v2 sin(2ρ2)
++Λ2v2v2
+3 sin(2(ρ2 − ρ3)) + Λ2v2
+1v2 sin(2ρ2) − Λ4v2v2
+3 cos(2(ρ2 − ρ3))
++Λ4v2
+1v2 cos(2ρ2) − 4Re(m2
+23)v3 sin(ρ2 − ρ3) − 4Re(m2
+12)v1 sin(ρ2)
+� �
+(95)
+Im(m2
+13) = − 1
+4v1
+�
+sec(ρ3)
+�
+4Im(m2
+23)v2 cos(ρ2 − ρ3) − Λ1v2
+2v3 sin(2(ρ2 − ρ3)) + Λ1v2
+1v3 sin(2ρ3)
++Λ2v2
+2v3 sin(2(ρ2 − ρ3)) − Λ2v2
+1v3 sin(2ρ3) − Λ4v2
+2v3 cos(2(ρ2 − ρ3))
++Λ4v2
+1v3 cos(2ρ3) − 4Re(m2
+23)v2 sin(ρ2 − ρ3) + 4Re(m2
+13)v1 sin(ρ3)
+� �
+(96)
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+
diff --git a/GNE3T4oBgHgl3EQftgtb/content/tmp_files/load_file.txt b/GNE3T4oBgHgl3EQftgtb/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..038103cfb827784b3333dde49f48417bec4f4505
--- /dev/null
+++ b/GNE3T4oBgHgl3EQftgtb/content/tmp_files/load_file.txt
@@ -0,0 +1,820 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf,len=819
+page_content='CFTP/23-001  A viable A4 3HDM theory of quark mass matrices  Iris Brée∗, Sérgio Carrôlo †, Jorge C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Romão ‡, João P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Silva §,  CFTP, Departamento de Física,  Instituto Superior Técnico, Universidade de Lisboa,  Avenida Rovisco Pais 1, 1049 Lisboa, Portugal  January 13, 2023  Abstract  It is known that a three Higgs doublet model (3HDM) symmetric under an exact A4 sym-  metry is not compatible with nonzero quark masses and/or non-block-diagonal CKM matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  We show that a 3HDM with softly broken A4 terms in the scalar potential does allow for a  fit of quark mass matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Moreover, the result is consistent with mh = 125GeV and the  h → WW, ZZ signal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We also checked numerically that, for each point that passes all the  constraints, the minimum is a global minimum of the potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  1  Introduction  The observation in 2012 of a scalar particle with 125GeV by the ATLAS and CMS collaborations  [1, 2] has incentivized experimental searches for beyond the Standard Model (SM) particles at the  LHC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' On par with these experimental endeavors, theoretical efforts in the search for extra scalar  particles have been strengthened since this discovery.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' A promising framework is found in N-Higgs  doublet models (NHDM).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Such models have many free parameters, which are often curtailed by imposing some discrete  family symmetry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Here, we focus on the implementation of A4 in a three Higgs doublet model  (3HDM).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The A4 group is the group of even permutations on 4 elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  It is the smallest  discrete group to contain a three-dimensional irreducible representation (irrep), which is ideal for  describing the three families of quarks with a minimal number of independent Yukawa couplings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Thus, NHDM supplemented by the A4 discrete symmetry has long been of interest in flavour  physics research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  A number of early articles include: [3], mainly devoted to the leptonic sector and where the  solution to the quark sector is briefly mentioned to include a fourth Higgs doublet and all quark  fields in singlets (which is effectively the same as the Standard Model quark sector);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [4], where A4  is broken by dimension four Yukawa couplings, thus rendering the theory non-renormalizable or,  alternatively, the low energy limit of a broader complete theory;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [5], which requires three Higgs  doublets in the down-type quark sector and a further two in the up-type quark sector, consisting  ∗iris.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='bree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='silva@tecnico.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='ulisboa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='pt  †sergio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='carrolo@tecnico.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='ulisboa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='pt  ‡jorge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='romao@tecnico.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='ulisboa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='pt  §jpsilva@cftp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='ist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='utl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='pt  1  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='04676v1  [hep-ph]  11 Jan 2023  of a 5HDM;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' and [6], which is devoted to the leptonic sector, but has the interesting side query  that it might be possible to recover a realistic CKM matrix through soft-breaking of A4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Quark mass matrices in the context of a 3HDM with Higgs doublets in the triplet representation  of A4 were studied in [7] and [8], with the vacuum expectation value (vev) structure (eiα, e−iα, r),  where α and r are real constants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Unfortunately, Degee, Ivanov and Keus [9] proved in 2013 that  such a vacuum can never be the global minimum of the A4 symmetric 3HDM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In this beautiful  paper, geometric techniques were used in order to identify all possible global minima (thus, all  possible viable vacua) of the A4 symmetric 3HDM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Immediately thereafter, those minima were  used to show that all assignments of the quark fields into irreps of A4, when combined with the  possible vevs for the exact A4 potential, yield vanishing quark masses and/or a CP conserving  CKM matrix, both of which are forbidden by experiment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This is in fact a consequence of a much  broader theorem, proved in [10, 11]: given any flavour symmetry group, one can obtain a physical  CKM mixing matrix and, simultaneously, non-degenerate and non-zero quark masses only if the  vevs of the Higgs fields break completely the full flavour group.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The idea is that a symmetry will  reduce the number of redundant Yukawa couplings present in the SM, and it might even predict  relations among observables which turn out to be consistent with experiment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  When studying in detail the extensions of A4 to the quark sector found by Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [12], we noticed  that, in some of them, if it weren’t for the particular form of the vevs allowed by the exact A4  3HDM potential, the Yukawa matrices could allow for massive quarks, and for a realistic CKM  matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Since the A4 symmetric potential doesn’t allow for minima other than those shown in [9],  here we consider the case where the A4 symmetry is softly broken by the addition of quadratic  terms to the potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Such terms do not spoil the theory’s renormalizability, but break the A4  symmetry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Our article is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We define the notation for the scalar potential in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1,  discuss the Yukawa Lagrangian and the form of the possible mass matrices in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2, giving all  the expressions needed for the fit in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3 we present our fit to the quarks mass  matrices, while in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 4 we discuss the viability of the vacuum found in the fit in terms of the  scalar potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 5 is devoted to the implementation of the theoretical constraints to be  imposed, and in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 6 we briefly discuss the constraints coming from the LHC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The results and  conclusions are presented in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 7 and 8, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The Appendices contain some additional  expressions that are needed for the fits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  2  Parameterization for the softly-broken A4 3HDM  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  Potential and candidates for local minimum  The softly-broken potential of the 3HDM with an A4 symmetry is given by  VH = V4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' A4 + M2  ij  �  φ†  iφj  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (1)  where V4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' A4 is the quartic potential for the A4 symmetric three Higgs doublet model (3HDM),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  which is,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' in the notation of [9],' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  2  V4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' A4 =Λ0  3  �  φ†  1φ1 + φ†  2φ2 + φ†  3φ3  �2  + Λ1  ��  Re  �  φ†  1φ2  ��2 +  �  Re  �  φ†  2φ3  ��2 +  �  Re  �  φ†  3φ1  ��2�  + Λ2  ��  Im  �  φ†  1φ2  ��2 +  �  Im  �  φ†  2φ3  ��2 +  �  Im  �  φ†  3φ1  ��2�  + Λ3  3  �  (φ†  1φ1)2 + (φ†  2φ2)2 + (φ†  3φ3)2 − (φ†  1φ1)(φ†  2φ2) − (φ†  2φ2)(φ†  3φ3) − (φ†  3φ3)(φ†  1φ1)  �  + Λ4  �  Re  �  φ†  1φ2  �  Im  �  φ†  1φ2  �  + Re  �  φ†  2φ3  �  Im  �  φ†  2φ3  �  + Re  �  φ†  3φ1  �  Im  �  φ†  3φ1  ��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (2)  The matrix M2  ij is a general hermitian matrix, which can be parameterized by  (M2  ij) =  �  �  �  m2  11  m2  12eiθ12  m2  13eiθ13  m2  12e−iθ12  m2  22  m2  23eiθ23  m2  13e−iθ13  m2  23e−iθ23  m2  33  �  �  � ,  (3)  where m2  ij are real parameters with the dimension of mass squared.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  Additionally, in the notation of [13], the exact A4 potential can be written as  VA4 =r1 + 2r4  3  �  (φ†  1φ1) + (φ†  2φ2) + (φ†  3φ3)  �2 + 2(r1 − r4)  3  �  (φ†  1φ1)2 + (φ†  2φ2)2  +(φ†  3φ3)2 − (φ†  1φ1)(φ†  2φ2) − (φ†  2φ2)(φ†  3φ3) − (φ†  3φ3)(φ†  1φ1)  �  + 2r7  �  |φ†  1φ2|2 + |φ†  2φ3|2 + |φ†  3φ1|2�  +  �  c3  �  (φ†  1φ2)2 + (φ†  2φ3)2 + (φ†  3φ1)2�  + h.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (4)  The relation between the two notations is  r1 = 1  3(Λ0 + Λ3) ,  r4 = 1  6(2Λ0 − Λ3) ,  r7 = 1  4(Λ1 + Λ2) ,  Re(c3) = 1  4(Λ1 − Λ2) ,  Im(c3) = −1  4Λ4 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (5)  We consider that the scalar fields can take complex vacuum expectation values (vevs), to be  determined later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Thus, we write,  φi =  �  ϕ+  i  |vi|eiρi  √  2  +  1  √  2 (xi + ixi+3)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (6)  Because CP is spontaneously violated, the unrotated neutral fields have no definite CP, and for  convenience we label them xi, i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' , 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We can also use the gauge freedom to absorb one of  the phases in the vevs, that we choose to be ρ1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Therefore we have the vector of vevs defined as  ⃗v = (|v1|, |v2|eiρ2, |v3|eiρ3) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (7)  1In the quadratic terms, the combination − M0  √  3  �  φ†  1φ1 + φ†  2φ2 + φ†  3φ3  �  is also invariant under A4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' But, since we  are keeping all soft-breaking terms, we find the notation in (3) more convenient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  3  This vev contributes with four free parameters to our model, because one of the parameters is  constrained by the mass of the gauge bosons to match the observed SM values,  |v1|2 + |v2|2 + |v3|2 ≡ v2 ≃ (246GeV)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (8)  The vev can also be parameterised as  ⃗v = v  �  cos(β1) cos(β2), cos(β2) sin(β1)eip2, sin(β2)eip3�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (9)  Of the quantities arising out of the scalar potential, the vevs are the only relevant to the quark  mass matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This leads many authors to just proclaim some vevs, without checking whether  they can indeed be the global minima of a realistic Higgs potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We will perform this crucial  verification below, in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  Yukawa Lagrangian  As in Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [7, 12], we consider that the Higgs doublets are in the 3 of A4 as well as the three  left-handed SU(2) doublets QLj of hypercharge 1/6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' There are three right-handed SU(2) singlets  nR,j of hypercharge −1/3 and three right-handed SU(2) singlets pR,j of hypercharge 2/3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Our  assignments for the singlets are as follows  nR1, pR1 → 1,  nR2, pR2 → 1′,  nR3, pR3 → 1′′ of A4 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (10)  Then, the A4 transformations on the fields are generated by [7, 12]  T :  �  �  �  �  �  �  �  �  �  �  �  φ1 → φ2 → φ3 → φ1,  QL1 → QL2 → QL3 → QL1,  nR1 → nR1, nR2 → ωnR2, nR3 → ω2nR3,  pR1 → nR1, pR2 → ωpR2, pR3 → ω2pR3,  (11)  and  S :  �φ1 → φ1, φ2 → −φ2, φ3 → −φ3,  QL1 → QL1, QL2 → −QL2, QL3 → −QL3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (12)  One can easily verify that the scalar potential in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (4) is invariant under the previous transfor-  mations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Now we write the A4 invariant Yukawa Lagrangian for quarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We have  −LYukawa =  √  2 ˆa  �  QL1φ1 + QL2φ2 + QL3φ3  �  nR1  +  √  2ˆb  �  QL1φ1 + ω QL2φ2 + ω2 QL3φ3  �  nR2  +  √  2 ˆc  �  QL1φ1 + ω2 QL2φ2 + ω QL3φ3  �  nR3  +  √  2 ˆa′ �  QL1 ˜φ1 + QL2 ˜φ2 + QL3 ˜φ3  �  pR1  +  √  2ˆb′ �  QL1 ˜φ1 + ω QL2 ˜φ2 + ω2 QL3 ˜φ3  �  pR2  +  √  2 ˆc′ �  QL1 ˜φ1 + ω2 QL2 ˜φ2 + ω QL3 ˜φ3  �  pR3 + h.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=',  (13)  4  where, as usual,  ˜φj ≡ i σ2φ∗  j ,  (14)  and we define  ˆa = aei α, ˆb = bei β, ˆc = cei γ, ˆa′ = a′ei α′, ˆb′ = b′ei β′, ˆc′ = c′ei γ′ ,  (15)  where a, b, c, a′, b′, c′ are real and positive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This choice of invariant Lagrangian corresponds to the  case I identified in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [12] (see the next section).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  Yukawa matrices, masses and CKM  We aim to fit six quark masses and four CKM matrix elements to the currently accepted SM  values for these observables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Therefore, we’re interested in softly-broken A4 symmetric models  with up to ten parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [12] has studied all of the possible extensions of A4 to the fermion  sector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Using their results, we can check which of them can accommodate non-vanishing quark  masses, CKM mixing angles and CP violation by considering a general vev ⃗v.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We take the Jarlskog  invariant as a measure of CP violation [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Out of all possibilities, we are left with five of them,  which we list in Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' There, A are real constants, Ω are constants in the [0, 2π[ interval,  ω = ei 2π  3 (ω3 = 1) and T is the transpose of the matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Case  Md  Mu  I  �  �  �  aeiαv1  beiβv1  ceiγv1  aeiαv2  ωbeiβv2  ω2ceiγv2  aeiαv3  ω2beiβv3  ωceiγv3  �  �  �  �  �  �  A → A′,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  A ∈ {a,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' b,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' c}  Ω → Ω′,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Ω ∈ {α,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' β,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' γ}  vi → v∗  i ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  i ∈ {1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3}  �  �  �  II  IT  d  IT  u  III  �  �  �  0  (aeiα − beiβ)v3  (aeiα + beiβ)v2  (aeiα + beiβ)v3  0  (aeiα − beiβ)v1  (aeiα − beiβ)v2  (aeiα + beiβ)v1  0  �  �  �  �  �  �  A → A′,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  A ∈ {a,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' b}  Ω → Ω′,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Ω ∈ {α,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' β}  vi → v∗  i ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  i ∈ {1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3}  �  �  �  IV  Id  IIIu  V  IIId  Iu  Table 1: Extensions of A4 to the Yukawa sector with non-vanishing determinant,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' and non-zero J  for general,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' complex valued,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' vevs (v1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' v2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' v3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In the Table, Id stands for the matrix Md for case I  and similarly for the other entries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  In the Yukawa sector, there are ten observables, six masses, three mixing angles and one  Jarlskog invariant, therefore, we would prefer to look for a case with ten parameters, or less.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' All  possible neutral vevs of the 3HDM are consistent with the parameterization in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (9), which  consists of four free parameters that we can fit;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' two angles, and two phases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Looking at the cases  in Table 1, we will see that it is possible to reduce the number of free parameters by performing  both basis transformations to right-handed quarks and global U(1)Y rephasings, both of which  have no effect on the physical predictions of the theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  For case I, the down quark mass matrices read  5  Md =  �  �  �  aeiαv1  beiβv1  ceiγv1  aeiαv2  ωbeiβv2  ω2ceiγv2  aeiαv3  ω2beiβv3  ωceiγv3  �  �  � = DvWDaDα,  (16)  where (remember that the vi are complex)  Dv = diag(v1, v2, v3) , Da = diag(a, b, c) , Dα = diag(eiα, eiβ, eiγ) , W =  �  �  �  1  1  1  1  ω  ω2  1  ω2  ω  �  �  � .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (17)  We see that we can perform a unitary transformation to the right-handed quarks that removes all  three phases α, β, γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The same holds for Mu, by performing the substitution A → A′, Ω → Ω′  and vi → v∗  i .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  For case II, the quark mass matrices have the form  Md = DaDαWDv and Mu = Da′Dα′WDv∗ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (18)  Thus, we can remove the phases of the vev through an appropriate transformation of the right-  handed quarks, but we can only remove α through a global rephasing QL → Q′  L = eiαQL of  the left-handed quarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This rephasing, however, doesn’t remove the phase α′ in the matrix Mu,  because, in general, it will be different from α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Now, for case III, we can only remove α and  α′ 2 by performing the corresponding rephasings of the right-handed quarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Finally, for the case  IV (V), we can remove, as we did for case I, all the phases from the Yukawa couplings α, β, γ  (corresponding primes), and only one phase α′ (corresponding unprimed).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' To summarise, we can  classify the cases above according to their number of free-parameters, which we show in the Table  below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  case  #θ  #p  #A  #α  #A′  α′  Total  I  2  2  3  3 − 3 = 0  3  3 − 3 = 0  10  II  2  2 − 2 = 0  3  3 − 1 = 2  3  3  13  III  2  2  2  2 − 1 = 1  2  2 − 1 = 1  10  IV  2  2  3  3 − 3 = 0  2  2 − 1 = 1  10  V  2  2  2  2 − 1 = 1  3  3 − 3 = 0  10  Table 2: Number of parameters for each case of Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' θ and p are the angles and phases of the  vev, A(A′) are the Yukawa couplings of the down (up) quarks, and α(α′) are the Yukawa phases  of the down (up) quarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The minus signs correspond to the parameters that we can remove by  a basis transformation of the quark sector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  In this work, we study case I, that corresponds to the Lagrangian in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (13).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Then, given  that DαD†  α = 1 and DaD†  a = Da2 = diag(a2, b2, c2), we find  Hd  ≡  MdM†  d = DvSdD†  v ,  Hu  ≡  MuM†  u = D†  vSuDv ,  (19)  2We could have chosen to remove β and β′ instead, this is just one possible choice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  6  where Sd = WDa2W † and a2 → a′2 for the up quark case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This matrix can now be explicitly  written out using appropriate parameters as  Sd =  �  �  �  Σd  Zdeiφd  Zde−iφd  Zde−iφd  Σd  Zdeiφd  Zdeiφd  Zde−iφd  Σd  �  �  � ,  (20)  where Σd and Zd are real, and  Σd  ≡  a2 + b2 + c2 ,  Zd eiφd  ≡  a2 + ω2b2 + ωc2 ,  (21)  with corresponding primes for the up case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  For completeness, the specific forms for Hd and  Hu found after using the parameterizations in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (9) and (21) are written in Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  The eigenvalues of the matrices Hd and Hu will be fitted for the (square of the) quark masses,  (m2  d, m2  s, m2  b) and (m2  u, m2  c, m2  t ), respectively  We now turn to the Cabibbo-Kobayashi-Maskawa (CKM) matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' As found by Branco and  Lavoura [15], the absolute values of the CKM matrix can be obtained through calculating the  traces of appropriate powers of the matrices Hu and Hd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' They observe that  Tr  �  Ha  uHb  d  �  ≡ Lab =  �  k,i  Uki(Da  u)kk(Db  d)ii ,  (22)  where Uki = |Vki|2 and V is the CKM matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The CKM matrix is unitary and therefore U only  has four independent entries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Consequently, in order to compute U, it is only necessary to resort  to  L11 =Uki(Du)kk(Dd)ii ,  L12 =Uki(Du)kk(D2  d)ii ,  L21 =Uki(D2  u)kk(Dd)ii ,  L22 =Uki(D2  u)kk(D2  d)ii .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (23)  These equations are linear in Uik and are, therefore, invertible for this variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Thus, by picking  U11, U21, U13, and U23 (respectively, Uud, Ucd, Uub, and Ucb), we are able to obtain a unique  solution for the magnitudes of the CKM elements as a function of Lab and the quark masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Namely,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  U11  =  �  mb2 − ms2� �  mc2 − mt2� a11  det ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  U21  =  �  mb2 − ms2� �  mu2 − mt2� a21  det ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  U13  =  �  md2 − ms2� �  mc2 − mt2� a13  det ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  U23  =  �  md2 − ms2� �  mu2 − mt2� a23  det ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (24)  where  a11  =  L11  �  mb2 + ms2� �  mc2 + mt2�  − L12  �  mc2 + mt2�  − L21  �  mb2 + ms2�  + L22  7  +m2  b  �  −m2  cm2  t  �  m2  d + m2  s  �  − m2  sm2  u  �  m2  c + m2  t  �  + m2  sm4  u  �  + m2  cm2  dm2  t  �  m2  d − m2  s  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(25)  a21  =  −L11  �  mb2 + ms2� �  mt2 + mu2�  + L12  �  mu2 + mt2�  + L21  �  mb2 + ms2�  − L22  +m2  b  �  m2  cm2  s  �  m2  t + m2  u − m2  c  �  + m2  t m2  u  �  m2  d + m2  s  ��  + m2  dm2  t m2  u  �  m2  s − m2  d  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (26)  a13  =  −L11  �  md2 + ms2� �  mt2 + mc2�  + L12  �  mc2 + mt2�  + L21  �  md2 + ms2�  − L22  +m2  bm2  cm2  t  �  m2  d + m2  s − m2  b  �  + m2  dm2  s  �  m2  c  �  m2  t + m2  u  �  + m2  u  �  m2  t − mu2��  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (27)  a23  =  L11  �  md2 + ms2� �  mt2 + mu2�  − L12  �  mu2 + mt2�  − L21  �  md2 + ms2�  + L22  +m2  t m2  u  �  m4  b − m2  b  �  m2  d + m2  s  �  − m2  dm2  s  �  + m4  cm2  dm2  s − m2  cm2  dm2  s  �  m2  t + m2  u  �  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (28)  and  det =  �  mb2 − md2� �  mc2 − mu2� �  md2 − ms2� �  mu2 − mt2� �  mb2 − ms2� �  mc2 − mt2�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (29)  In these equations, the Lij are obtained by evaluating the left hand side of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Finally, we  note that knowing these four CKM magnitudes, we can determine the Jarslkog invariant [14], up  to its sign.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Thus, given some phase convention, we are also able to determine the phases of all  CKM matrix elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  3  The fit to the quark mass matrices  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  The fitting procedure  We have implemented a χ2 analysis of the model, through a minimization performed using the  CERN Minuit library [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The observables employed in this analysis, labeled by i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=', 11 are  specified in Table 3, where Xi represents the experimental mean value of the observable Xi and  σi is the experimental error, which, when both left and right bounds are stated, is assumed to be  the largest of the two.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The data on the quark masses as well as for the CKM matrix elements and  Observable  Experimental value  Model prediction  mu [MeV]  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='16 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='50  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='15  mc [MeV]  1270 ± 20  1271.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='9  mt [GeV]  172.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='69 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='30  172.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='69  md [MeV]  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='67 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='50  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='66  ms [MeV]  93.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4 ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='6  92.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='08  mb [MeV]  4180 ± 30  4179.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='74  |V11|  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='97435 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00016  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='97434  |V21|  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='22486 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00067  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='22479  |V13|  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00369 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00011  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00369  |V23|  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='04182 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00085  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='04175  J  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='08 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='15) × 10−5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='09 × 10−5  Table 3: Experimental values and fit results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  the Jarlskog invariant experimental values were obtained from [17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' As mentioned, |J| is fixed by  |V11|, |V21|, |V13|, and |V23|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' However, using it in the fit speeds the numerical convergence onto a  good solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  8  The χ2 function depends on the 10 parameters of our model,  β1, β2, ρ2, ρ3, Σd, Σu, Zd, Zu, φd, φu  (30)  and is written as  χ2(p) =  11  �  i=1  �  Pi(p) − Xi  σi  �2  ,  (31)  where Pi(p) is our model’s prediction for each of the 11 (10 + J) observables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The fit is complicated  by the fact that the masses (squared) are obtained from the eigenvalues of Hd, Hu but the elements  of the CKM also depend on the masses, see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (24).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' So, we start by calculating the eigenvalues  of Hd and Hu, which depend only on the parameters in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (30).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Then, we evaluate the Lij  from the left hand side of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (22), and finally the CKM elements are obtained from Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (24).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In  Appendix A we give the explicit expressions for the matrices Hd and Hu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  Results of the fit  We have found an excellent fit of our model to the data, given in the second column of Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  This fit results in χ2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='058, for the parameters  β1 =1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='42608 radians ,  β2 =1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='54243 radians ,  ρ2 =4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='27865 radians ,  ρ3 =5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='37039 radians ,  Σd =0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='288824 × 10−3 ,  Σu =0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='492828 ,  Zd =0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='181571 × 10−3 ,  Zu =0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='475911 ,  φd = − 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='73226 radians ,  φu =0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='206453 × 10−3 radians .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (32)  This fit also leads to the data in the third column of Table 3, as well as to the vevs  |vi| = (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00625, 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='90462, 245.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='901) (GeV).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (33)  We notice that the vevs obey v1 < v2 << v3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This hierarchy of vevs is related to the hierarchy of  the quark masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This was also obtained in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [7], although their model is not consistent, as  their vev structure is not that of [9] for the symmetric A4 potential they consider.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  4  Viability of the vacuum found in the fit  We start by defining the three doublets as in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Next we define the physical eigenstates for  the charged Higgs as (G+, S+  2 , S2  3)T , and for the neutral states we have (G0, S0  2, S0  3, S0  4, S0  5, S0  6)T ,  identifying the would-be Goldstone bosons G+ ≡ S+  1 and G0 ≡ S0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' With these conventions, and  following the definitions in [18], we define the 3 × 3 matrix ˜U by  ϕ+  i ≡  3  �  j=1  ˜UijS+  j ,  (34)  9  and the 3 × 6 matrix ˜V by  xi + ixi+3 =  6  �  j=1  ˜VijS0  j .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (35)  These matrices3 are then related to the diagonalization matrices of the charged and neutral scalars,  to which we now turn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  The minimization of the potential  In our procedure we already know the values of the vevs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' So, we use the stationarity equations  to solve for the soft parameters, and leave the quartic parameters of the potential Λi as free  parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In this way we can solve for m2  11, m2  22, m2  33 as well as for Im(m2  12), Im(m2  13), leaving  as free parameters the Λi and Re(m2  12), Re(m2  13), Re(m2  23), Im(m2  23).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' When evaluating the scalar  mass matrices (see below) the conditions have to be applied to ensure that we are at the minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  For completeness we write these conditions in Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  The charged mass matrix  The charged mass matrix is obtained from the second derivatives at the minimum,  M2  C =  ∂2VH  ∂ϕ+  i ∂ϕ−  j  �����  Min  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (36)  The matrix M2  C is an hermitian matrix, with real eigenvalues and satisfying, with our usual  conventions,  RchM2  CR†  ch = diag(0, m2  S+  2 , m2  S+  3 ) ≡ M2  Dch ,  (37)  where Rch is an unitary matrix that satisfies,  S+  i =  3  �  j=1  (Rch)ij ϕ+  j .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (38)  This can be seen from  Lmass = − ϕ−  i  �  M2  C  �  ij ϕ+  j = −ϕ−  i  �  R†  chRchM2  CR†  chRch  �  ij ϕ+  j = −ϕ−  i  �  R†  chM2  DchRch  �  ij ϕ+  j  = − S−  i  �  M2  Dch  �  ij S+  j ,  (39)  where we have used Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (38).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  We have checked both algebraically and numerically that we have a zero eigenvalue corre-  sponding to G+ and we require that all other masses squared are positive, a condition for a local  minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  3From the point of view of a simultaneous fit of the Yukawa and scalar sectors, it is a pity that these matrices  ˜V and ˜U have in the literature the same notation as the CKM matrix V and Uki = |Vki|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  10  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  The neutral mass matrix  Since in our case CP is not conserved, we denote the unrotated neutral scalars by xi, i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' , 6,  as in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We therefore obtain the neutral mass matrix as,  M2  N =  ∂2VH  ∂xi∂xj  �����  Min  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (40)  This is a symmetric real matrix diagonalized by an orthogonal 6 × 6 matrix,  RneuM2  NRT  neu = diag(0, m2  S0  2, m2  S0  3, m2  S0  4, m2  S0  5, m2  S0  6) ≡ M2  Dneu ,  (41)  with  S0  i =  6  �  j=1  (Rneu)ij xj .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (42)  As for the case of the charged scalars, we have checked both algebraically and numerically that  we have a zero eigenvalue corresponding to G0 and we require that all other masses squared are  positive, a condition for a local minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  5  Theoretical Constraints  After having shown that a solution exists for the vevs and parameters in the Yukawa sector that  correctly fits the quarks masses and the CKM entries, we have to show that this is compatible  with the scalar potential analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In particular we have to show that the vevs correspond to a  local minimum of the potential and that both the theoretical constraints as well as those coming  from LHC are satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In this section we analyze the theoretical constraints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  Perturbative Unitarity  This problem was already solved in [13], so we take the potential in the form of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' From  Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [13] we have the following expression for the eigenvalues λi4  λ1 =2 (2Re(c3) + r1)  (43)  λ2 =2  �√  3 |Im(c3)| − Re(c3) + r1  �  (44)  λ3 =2  �  −  √  3 |Im(c3)| − Re(c3) + r1  �  (45)  λ4 =2(r4 + r7)  (46)  λ5 =2(r4 − r7)  (47)  λ6 =2(r1 + 2r7)  (48)  λ7 =2(r1 − r7)  (49)  λ8 =2(r4 + |c3|)  (50)  λ9 =2(r4 − |c3|)  (51)  λ10 =6r1 + 8r4 + 4r7  (52)  λ11 =6r1 − 2(2r4 + r7)  (53)  λ12 =6|c3| + 2r4 + 4r7  (54)  4We use λi instead of Λi, in order to not confuse with the notation of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  11  λ13 = − 6|c3| + 2r4 + 4r7  (55)  Perturbative unitarity is satisfied if  |λi| < 8π,  ∀i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (56)  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  The BFB conditions  For the A4 symmetric potential, the conditions for boundedness from below along the neutral  directions (BFB-n) have been conjectured in [19], and proved to hold in [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' These are  Λ0 + Λ3 ≥ 0 ,  (57)  4  3(Λ0 + Λ3) + 1  2(Λ1 + Λ2) − Λ3 − 1  2  �  (Λ1 − Λ2)2 + Λ2  4 ≥ 0 ,  (58)  Λ0 + 1  2(Λ1 + Λ2) + 1  2(Λ1 − Λ2) cos (2kπ/3) + 1  2Λ4 sin (2kπ/3) ≥ 0  (k = 1, 2, 3) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (59)  However, as shown in [21, 19], a potential which is BFB-n is not necessarily BFB along the  charge breaking directions (BFB-c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Necessary BFB-c conditions have yet to be found for the A4  3HDM, but sufficient conditions have been proposed in [22] following the technique developed in  [23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' They are,  Ad ≥ 0 ,  Ao ≥ −Ad/2 ,  (60)  where  Ad =a = 2  3(Λ0 + Λ3) ,  Ao =b + min(0, c) − d  =1  3(2Λ0 − Λ3) + 1  2(Λ1 + Λ2) + min(0, −1  2(Λ1 + Λ2)) − 1  2  �  (Λ1 − Λ2)2 + Λ2  4 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (61)  It is important to remark that, since these are sufficient, but not necessary, conditions, some  good points in parameter space may be excluded by this restriction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  The oblique parameters S, T, U  For this we use the notation and results from [18], which require the matrices ˜U and ˜V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Comparing  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (38) with the definition in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (34), we conclude that  ˜U = R†  ch ,  (62)  where the matrix Rch is obtained from the numerical diagonalization of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (37).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Similarly,  comparing Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (42) with the definition of ˜V in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (35), we get,  ˜Vij =  �  RT  neu  �  ij + i  �  RT  neu  �  i+3,j .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (63)  Having ˜U and ˜V , we can construct the needed matrices Im  � ˜V † ˜V  �  , ˜U† ˜U, ˜V † ˜V and ˜U† ˜V , and  implement the procedure of [18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  12  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  Global minimum  After finding a set of mi,j and Λi which reproduce the vevs in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (33) necessary for a good fit  of the quark mass matrices, and after performing the previous theoretical checks on the scalar  potential, we must still ensure that our minimum is indeed the global minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This step is  almost never taken in studies of quark mass matrices, since there are no exact analytical formulae  for it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Moreover, one must check that there are no lower minima both along the neutral directions  and along the charge breaking directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We follow the strategy discussed in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' [22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Take a  specific set of m2  ij and Λi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Then we parameterize the scalar doublets as [21, 22],  ⟨φ1⟩ = √r1  �  0  1  �  ,  ⟨φ2⟩ = √r2  �  sin(α2)  cos(α2)eiβ2  �  ,  ⟨φ3⟩ = √r3eiγ  �  sin(α3)  cos(α3)eiβ3  �  ,  (64)  where we have already used the gauge freedom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Now we let the vevs run free, for both charge  conserving and charge violating directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We give one seed point and perform a minimization of  the potential using the CERN Minuit library [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We obtain not only the value of the potential  at the minimum, but also the values of ri, α2, β2, α3, β3 and γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Then, we take one more (randomly  generated) seed point and repeat the minimization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Finally, we take the minimum as the global  one if it is found as the global minimum in each of 200 searches with randomly generated seed  points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We have done this verification for every point that passed all the constraints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In all cases,  we found that the local minimum was also a global minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In particular we always found that  sin(α2) = sin(α3) = 0,  (65)  showing that we do not have charged breaking directions5 and, comparing with Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (6), we verified  numerically that,  |vi|  √  2 = √ri,  ei ρ2 = cos(α2) ei β2,  ei ρ3 = cos(α3) ei (β3+γ) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (66)  6  Simple LHC Constraints  Up to now we have implemented the theoretical constraints on the model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' The next step is to  implement the LHC constraints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' To do this completely one would have to implement all the decays  of the neutral and charged Higgs as well as their branching ratios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' One would also have to worry  about the electric dipole moments (EDM) and the flavour-changing neutral couplings (FCNC), as  the model does not have a structure of couplings of the Higgs to the fermions that automatically  ensures vanishing FCNC [24, 25, 26].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This lies beyond the scope of the present work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Nonetheless,  we can implement easily the constraints that come from h → WW/ZZ in the κ formalism, where  the deviation from the coupling of the SM Higgs boson to a pair of W’s (or Z’s) is measured by  κV .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In our model,  κV = Rneu  21 v1 + Rneu  22 v2 cos(ρ2) + Rneu  23 v3 cos(ρ3) + Rneu  25 v2 sin(ρ2) + Rneu  26 v3 sin(ρ3),  (67)  where Rneu is matrix defined in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (41).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We take the experimental constraint from ATLAS [27],  κW = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='0206 +0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='05172  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='05087,  κZ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='99 +0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='06136  −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='05214 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (68)  5To cross check our numerical procedure we also considered points that violated the BFB conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' And, indeed  for these points, our algorithm showed that the potential was not BFB and could have charge breaking directions  as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  13  7  Results  In this section we present the results of the analysis of the scalar potential after imposing that we  have a good solution for the fit of the quarks masses and CKM entries, as explained in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  Scanning strategy  We start by imposing the vevs obtained in the fit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  v1 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='00625 (GeV),  v2 = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='90462 ei 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='27865 (GeV),  v3 = 245.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='901 ei 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='37039 (GeV).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (69)  Now we vary the free parameters of the potential in the following ranges,  log10 |Λi| ∈ [−3, 1],  log10 |Im(m2  23)| ∈ [−1, 7]GeV2,  log10 |Re(m2  ij)| ∈ [−1, 7]GeV2,  (70)  where in the last equation we use  m2  ij ∈  �  m2  12, m2  13, m2  23  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (71)  We randomly scan as in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (70), and then:  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Apply the theoretical constraints that only depend on the Λi, that is BFB and perturbative  unitarity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Then obtain the eigenvalues for the charged and neutral scalars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Verify that all the masses  squared are positive, and that we have a zero eigenvalue corresponding to the Goldstone  bosons, G0 and G+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Verify the S, T and U oblique parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Apply the LHC constraint on κV .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Check numerically that the vev is indeed a global minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  The scalar spectrum  We found that there is a strong correlation in the scalar masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  If we denote the masses of  the neutral scalars by (mG0 = 0, mS0  2, mS0  3, mS0  4, mS0  5, mS0  6), and (mG+ = 0, mH+  1 , mH+  2 ) for the  charged scalars, we find numerically that  mS0  3 ≃ mS0  4 ≃ mH+  1 ,  mS0  5 ≃ mS0  6 ≃ mH+  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (72)  This is true even if we do not require mS0  2 = 125 GeV, and specially true after implementing  the constraints of perturbative unitarity, BFB and STU.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' But, as we want to reproduce the LHC  results, we also required that [17]  mS0  2 = 125.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='25 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='17  GeV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  (73)  In the following figures we show the correlation among the masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Included in red are the  points generated before the theoretical cuts were applied, and in green the points remaining after  the constraints were implemented.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  14  Figure 1: Left panel: Relation between mS0  3 and mS0  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Right panel: Relation between mS0  3 and  mH+  1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Color conventions: No cuts (red);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' with cuts (green)  Figure 2: Left panel: Relation between mS0  5 and mS0  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Right panel: Relation between mS0  5 and  mH+  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Color conventions: No cuts (red);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' with cuts (green)  15  2000  1500  1000  500  0  500  1000  1500  2000  ms (GeV)2000  1500  mHt (GeV)  1000  500  0  500  1000  1500  2000  ms (GeV)2000  1500  1000  500  0  500  1000  1500  2000  msg (GeV)2000  1500  (GeV)  1000  500  0  500  1000  1500  2000  msg (GeV)Figure 3: Left panel: Relation between mS0  3 and mS0  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Right panel: Relation between mH+  1 and  mH+  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Color conventions: No cuts (red);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' with cuts (green)  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  The κV constraint  We can now implement the κV constraint on the model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In the following figures, in red are points  without cuts, in green with cuts but no κV constraint, and finally in blue points remaining after  this constraint is applied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We took the ATLAS result of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' (68) at 2σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' While the theoretical  constraints cut around 99% of the points, the κV constraint only cuts 9% of the remaining points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 4 we show the relation between κV and Λ0,4 for the three sets of points as discussed above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Figure 4: Left panel: Relation between κV and Λ0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Right panel: Relation between κV and Λ4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Color conventions: No cuts (red), with theoretical cuts (green), and after the κV constraint (blue).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  In fact it is not obvious from Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 4 that the κV constraint only cuts about 9% of the points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  This is because there is a very large number of points with |κV | ≲ 1, even without theoretical  cuts, and this is even more so after imposing the theoretical cuts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In this figure, we have 157810  points in the green region, but from these 145074 are in the blue region.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' That is, after theoretical  16  2000  1500  1000  500  500  1000  1500  2000  ms (GeV)2000  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='.  1500  (GeV)  1000  H  500  500  1000  1500  2000  mHt (GeV)10  5  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='5  10  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='8  [Ky]10  4  5  10  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='8  [Kvlcuts, 91% of the points also satisfy the κV constraint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 5 we show the relation between Λ0  and Λ3,4 for the same sets of points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  Figure 5: Left panel: Relation between Λ0 and Λ4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Right panel: Relation between Λ0 and Λ3  Color conventions: No cuts (red), with theoretical cuts (green), and after the κV constraint (blue).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  We see that, while for (Λ0, Λ4) there is not much difference before and after the κV constraint,  the same is not true for (Λ0, Λ3), where the constraints impose a linear relation between those  two parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  8  Conclusions  It is known that the 3HDM symmetric under an exact A4 symmetry is not compatible with non-  zero quark masses and/or non-block-diagonal CKM matrix [12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' In this work, we studied a 3HDM  with A4 softly broken.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This allows us to evade the above result, by enlarging the structure of the  possible vacua.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  We obtained an excellent fit of the quarks mass matrices, including the CP-violating Jarlskog  invariant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' This leads to a unique solution for the vevs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We showed that, with the solution for the  vevs obtained from the fit, it is possible to have a local minimum of the potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We enforce  this by imposing that all squared masses are positive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' As in our scheme the scalar masses are not  input parameters, we have to restrict one of the neutral scalars to have the mass of the known  Higgs boson.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  We have implemented the BFB, perturbative unitarity and the oblique parameters S, T, U  theoretical constraints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  From LHC, we have considered the observed Higgs mass and the κV  constraint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='6 After imposing the other constraints, we found that most of the points are close to  the alignment required to respect the experimental κV constraint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' We have discovered a strong  correlation among the masses of the scalars, even before applying the theoretical constraints,  especially for moderate to large scalar masses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  One important point is that we have numerically checked for all the points that pass our  constraints, that for a given set of parameters of the potential, our minimum is the true global  minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  6The detailed study of other LHC constraints as well as those coming from FCNC and the EDM lies beyond the  scope of the present work, and is left for a future publication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  17  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  0  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='6  No0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  2  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4  NoAcknowledgments  This work is supported in part by FCT (Fundação para a Ciência e Tecnologia) under Contracts  CERN/FIS-PAR/0002/2021, CERN/FIS-PAR/0008/2019, UIDB/00777/2020, and UIDP/00777/2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  these projects are partially funded through POCTI (FEDER), COMPETE, QREN, and the EU.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  The work of I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' was supported by a CFTP fellowship with reference BL210/2022-IST-ID and the  work of S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' by a CFTP fellowship with reference BL255/2022-IST-ID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  A  The matrices Hd and Hu  Hd(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 1) =Σdv2 cos2(β1) cos2(β2)  (74)  Hd(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2) =v2Zd cos(β1) cos2(β2) cos(ρ2 − φd) sin(β1)  − i v2Zd cos(β1) cos2(β2) sin(β1) sin(ρ2 − φd)  (75)  Hd(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3) =v2Zd cos(β1) cos(β2) cos(ρ3 + φd) sin(β2)  − i v2Zd cos(β1) cos(β2) sin(β2) sin(ρ3 + φd)  (76)  Hd(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 1) =(Hd(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2))∗  (77)  Hd(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2) =Σdv2 cos2(β2) sin2(β1)  (78)  Hd(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3) =v2Zd cos(β2) cos(ρ2 − ρ3 + φd) sin(β1) sin(β2)  + i v2Zd cos(β2) sin(β1) sin(β2) sin(ρ2 − ρ3 + φd)  (79)  Hd(3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 1) =(Hd(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3))∗  (80)  Hd(3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2) =(Hd(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3))∗  (81)  Hd(3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3) =Σdv2 sin2(β2)  (82)  Hu(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 1) =Σuv2 cos2(β1) cos2(β2)  (83)  Hu(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2) =v2Zu cos(β1) cos2(β2) cos(ρ2 − φu) sin(β1)  − i v2Zu cos(β1) cos2(β2) sin(β1) sin(ρ2 − φu)  (84)  Hu(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3) =v2Zu cos(β1) cos(β2) cos(ρ3 + φu) sin(β2)  − i v2Zu cos(β1) cos(β2) sin(β2) sin(ρ3 + φu)  (85)  Hu(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 1) =(Hu(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2))∗  (86)  Hu(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2) =Σuv2 cos2(β2) sin2(β1)  (87)  Hu(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3) =v2Zu cos(β2) cos(ρ2 − ρ3 + φu) sin(β1) sin(β2)  + i v2Zu cos(β2) sin(β1) sin(β2) sin(ρ2 − ρ3 + φu)  (88)  Hu(3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 1) =(Hu(1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3))∗  (89)  Hu(3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 2) =(Hu(2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3))∗  (90)  Hu(3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' 3) =Σuv2 sin2(β2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(91)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='B  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='The minimization conditions  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='11 = − sec(ρ2) sec(ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='24v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='−12Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='23)v2v3 sin(2(ρ2 − ρ3)) + cos(ρ2 − ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4Λ0v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='18  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+6Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 + 6Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 + 3Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 − 3Λ2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 + 2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 − v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 − v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='��  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+4Λ0v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 cos(ρ2 + ρ3) + 4Λ0v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 cos(ρ2 + ρ3) + 4Λ0v4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 cos(ρ2 + ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+6Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 cos(ρ2 + ρ3) + 6Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 cos(ρ2 + ρ3) − 3Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 cos(3(ρ2 − ρ3))  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+3Λ2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 cos(3(ρ2 − ρ3)) − 2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 cos(ρ2 + ρ3) − 2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 cos(ρ2 + ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+4Λ3v4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 cos(ρ2 + ρ3) + 3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 sin(ρ2 − ρ3) + 3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 sin(ρ2 + ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sin(ρ2 − ρ3) − 3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sin(ρ2 + ρ3) − 3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sin(ρ2 − ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sin(3(ρ2 − ρ3)) − 12Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='23)v2v3 cos(2(ρ2 − ρ3))  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+24Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='13)v1v3 cos(ρ2) + 24Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='12)v1v2 cos(ρ3) + 12Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='23)v2v3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(92)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='22 = −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='12v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sec(ρ2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='−4Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='23)v3 sin(ρ3) + v2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3(Λ1 − Λ2) cos(ρ2 − 2ρ3) − Λ4v2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sin(ρ2 − 2ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+4Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='23)v3 cos(ρ3) + 4Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='12)v1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+ v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4Λ0v2 + 6Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 + 3Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 + 3Λ2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='−2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 + 4Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 − 2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 + 3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 tan(ρ2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='� �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(93)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='33 = −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='12v3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sec(ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='2v3 sin(2ρ2 − ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='23)v2 cos(ρ2) + 4Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+ v3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4Λ0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+ 6Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 + 3Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+3Λ2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='2 − 2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 − 2Λ3v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='3 − 3Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1 tan(ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='� �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(94)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='4v1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='sec(ρ2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='+Λ2v2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='3 sin(2(ρ2 − ρ3)) + Λ2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='3 cos(2(ρ2 − ρ3))  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='+Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v2 cos(2ρ2) − 4Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='� �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(95)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='4v1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='sec(ρ3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4Im(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='23)v2 cos(ρ2 − ρ3) − Λ1v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='2v3 sin(2(ρ2 − ρ3)) − Λ2v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='1v3 sin(2ρ3) − Λ4v2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='1v3 cos(2ρ3) − 4Re(m2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='� �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='(96)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='References  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='[1] ATLAS collaboration,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Observation of a new particle in the search for the Standard Model  Higgs boson with the ATLAS detector at the LHC,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content=' Peinado, An A4 model for lepton masses and mixings, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content=' D80  (2009) 113011 [0910.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='4389].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  [9] A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content=' Degee, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+page_content='00092].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
+page_content='  21' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/GNE3T4oBgHgl3EQftgtb/content/2301.04676v1.pdf'}
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+XXX-X-XXXX-XXXX-X/XX/$XX.00 ©20XX IEEE
+An Image captioning algorithm based on the Hybrid Deep Learning
+Technique (CNN+GRU)
+Rana Adnan Ahmad
+Department of Computer Science
+Comsats university islamabad, sahiwal
+campus,Sahiwal,Pakistan
+rana22293@gmail.com
+Muhammad Azhar
+Department of computer science
+Comsats university islamabad, sahiwal
+campus,Sahiwal,Pakistan
+azhar.cs@cuisahiwal.edu.pk
+Chosun University, Republic of Korea
+Muhammad.azhar@chosun.ac.kr
+Hina Sattar
+Department of computer science
+Comsats university islamabad, sahiwal
+campus, Sahiwal, Pakistann
+hinasattar987@gmail.com
+Abstract—
+Image
+captioning
+by
+the
+encoder-decoder
+framework has shown tremendous advancement in the last
+decade where CNN is mainly used as encoder and LSTM is
+used as a decoder. Despite such an impressive achievement in
+terms of accuracy in simple images, it lacks in terms of time
+complexity and space complexity efficiency. In addition to this,
+in case of complex images with a lot of information and objects,
+the
+performance
+of
+this
+CNN-LSTM
+pair
+downgraded
+exponentially due to the lack of semantic understanding of the
+scenes presented in the images. Thus, to take these issues into
+consideration,
+we
+present
+CNN-GRU
+encoder
+decode
+framework for caption-to-image reconstructor to handle the
+semantic context into consideration as well as the time
+complexity. By taking the hidden states of the decoder into
+consideration, the input image and its similar semantic
+representations is reconstructed and reconstruction scores
+from a semantic reconstructor are used in conjunction with
+likelihood during model training to assess the quality of the
+generated caption. As a result, the decoder receives improved
+semantic
+information,
+enhancing
+the
+caption
+production
+process. During model testing, combining the reconstruction
+score and the log-likelihood is also feasible to choose the most
+appropriate caption. The suggested model outperforms the
+state-of-the-art LSTM-A5 model for picture captioning in
+terms of time complexity and accuracy.
+Index Terms— Deep Learning, Image captioning, CNN, GRU
+1.
+INTRODUCTION
+Deep Learning has made great strides recently due to rapid
+growth and high utilization [1-4]. Thus, similar to Neural
+Machine Translation (NMT)[5], generating captions of the
+images through neural encoder-decoder framework has
+shown the dominance in recent years. In this process of
+image captioning, encoding of the image is done through
+encoder which is typically from the Convolutional Neural
+Networks (CNN) [6] family (like Vanilla CNN [6], Region
+based CNN [7], Fast R-CNN [8], Faster R-CNN [9] etc.) and
+decoder is from the RNN family [10] (like LSTM [11],
+BLSTM [12] etc.). In this framework of CNN-LSTM pair
+[13-16], the encoder (CNN) learns the visual features by
+making the feature maps and max-pooling during the feature
+learning stage and then detection of objects after flattening
+and applying fully connected layer. Thus it converts the
+image to vector of numbers which is learned form of the
+visual content of the image under consideration. In the
+decoder part, the vector output of the encoder is used as the
+initial input of the decoder to produce caption word by word.
+Even though Long Short Term Memory (LSTM) solves the
+issue of handling long dependency by decreasing the effect
+of
+exploding
+and
+vanishing
+gradients
+[11],
+the
+time
+complexity issue is still a major drawback in this model due
+to
+many
+gates
+residing
+in
+the
+LSTM
+unit
+for
+the
+memorization purpose. Another key issue with these kind of
+encoder-decoder models are the lack of understanding of the
+semantic context as the encoder of these models fail to
+transfer the major key visual information to the decoder.
+Because of the absence of reverse dependency checking
+(Caption-to-Image), these models do not perform well in
+case of complex images.
+Several approaches have been proposed to deal with the
+above-mentioned issues [17-20]. Some researches have
+proposed the attention mechanism to get the information
+from the key regions automatically and tried to encode that
+specific information into the context vector which then used
+by the decoder to generate the caption [17,18]. Some other
+researchers have tried to extract semantic attributes as a
+supplement of the CNN features to embed into encoder by
+various methods [19, 20].
+The major drawback of all the above mentioned methods
+was that those methods only explore the image-to-caption
+dependency but not the reverse way for the validation of the
+extracted information. Even though, Jinsong Su et.el. [21]
+have tried to use the semantic reconstructor of caption-to-
+image but still they could not
+validated the results in
+effective way. In addition to this, the time complexity issue
+was also remained due to the usage of LSTM unit.
+To resolve the above mentioned issues, we have proposed a
+hybrid deep learning technique based on the CNN-GRU
+encoder-decoder gramework with the better hyper-parameter
+tuning and with the caption-to-image validation method by
+taking the motivation from Jinsong Su et.el. [21]. This
+caption-to-image reconstructor helps to handle the semantic
+context into consideration as well as the time complexity. By
+taking the hidden states of the decoder into consideration, the
+input image and its similar semantic representations is
+reconstructed and reconstruction scores from a semantic
+reconstructor are used in conjunction with likelihood during
+model training to assess the quality of the generated caption.
+As a result, the decoder receives improved semantic
+information, enhancing the caption production process.
+During model testing, combining the reconstruction score
+and the log-likelihood is also feasible to choose the most
+appropriate caption.
+To validate our proposed method, we have used the
+benchmark MS COCO dataset [22] and the experimental
+results have proved that our method outperformed the current
+state-of-the-art methods in terms of accuracy and time
+complexity.
+2.
+RELATED WORK
+
+Inspiration for our work comes from the auto encoder [23,24]
+and how well it performs in NMT [25], which employs
+semantic production to hone the learning representation of
+input data. In this activity, we are fine-tuning the idea with
+captions to the image. Basically, related work involves
+taking after two strands. In general, NMT's common hands
+are very much based on the demonstration of source-to-target
+interpretation. Encouraged by questions about the auto
+encoder that makes reproduction more realistic and looking
+at whether the recreated inputs are more reliable than the
+original inputs [26], many analysts are committed to using
+the adaptation of dual-directed NMT conditions [27].
+Compared with NMT, most models of neural image captions
+are based on the neural encoder-decoder system [30].
+However, this engineer cannot guarantee that the image data
+can be completely converted into a decoder. To discuss this
+problem, analysts are currently accepting to take after two
+types of approaches: (1) As in NMT attention [31], a few
+analysts link part of the visual considerations to capture the
+semantic presentations of critical image regions [32,33]. (2)
+In various ways, a number of analysts are committed to
+extract semantic features or high-level concepts into images,
+which can be integrated into an LSTM-based decoder as an
+additional input [28,29]. In this way, the show will be
+directed to settings that are closely related to the theme of the
+image. Besides, You et al. [34] encompassed the two types
+of methods listed above.
+Our proposed representation is based on the CNN-LSTM
+model, in which the proposed semantic reconstructor is
+comparably compared to the LSTM, which is why it benefits
+both to display preparation and testing when the regional
+language indicate and the coding system are modeled
+independently. From Wena et al. [35] Institution devoted to
+improving
+automatically
+generated
+image
+captions
+by
+making inferences about their semantic content. However,
+the visual highlights are generally employed as the decode of
+the decoder in the current model captions, while the semantic
+elements of the image are provided exclusively to the
+decoder. As a result, we agree that visual robustness is more
+crucial than semantic characteristics. Through this research,
+we provide semantic features to neural machine translation
+as
+well
+as
+video
+captions.
+In
+conclusion,
+we
+are
+experimenting
+with
+three
+different
+methods
+for
+reconstructing
+photos
+based
+on
+fabricated
+captions.
+Additionally, our claim may be distinct from earlier studies
+due to K's extensive utilization of visually similar photos.
+3.
+PROPOSED MODEL
+This section describes the proposed hybrid deep learning
+approach based on CNN-GRU encoder-decoder framework.
+This framework has 3 major parts, 1) Encoder: which is the
+CNN. 2) Decoder: which is the GRU layer and 3) The
+Semantic validator: for validation of the caption-to-image
+information.
+A.
+Model architecture
+The three neural network modules (Encoder, Decoder, and
+Semantic validator) that make up our proposed model are
+depicted in Fig. 1. The details of each module is given below:
+
+Encoder
+In encoder, a model similar to [36] has been used where the
+image I is taken as input and the features from the image F is
+extracted by the CNN-based encoder. The feature vector F
+∈ RDv is used to represent the features extracted from the
+image I. Dv represents the diemnsions of the feature vector.
+As all the sementic information can not be extracted by one
+feature vector, thus additional semantic attributes have been
+extracted by the algorithm proposed by Yao et al. [36]. The
+extracted attribute vector is denoted by A ∈ RDa which
+shows the probabilty of each high level attribute existed in
+the caption dataset which is generated by the MIL (Multiple
+Instance Learning) model presented in [27]. MIL model
+showed the promising results in finding the semantic
+relations between the attributes of the image. Da represents
+the diemnsions of the attribute vector A.
+After extracting both feature map F and attribute vector A,
+the encoder gives these 2 outputs to decoder as an input
+which is used for the caption generation purpose.
+
+Decoder
+As we got feature vector F and the attribute vector A as an
+output of the encoder from previous network, this F and A is
+used as the input to the decoder for the caption generation.
+Yao et al. [36] proposes 5 different and diverse variants for
+the LSTM network and it is proved that the fifth one named
+LSTM-A5 works better than others, so we also used the same
+network for getting the better performance. Thus, according
+to LSTM-A5, we used the A and F vectors to calculate the log
+Probability Ɛ as mentioned in Equation (1).
+Ɛ(S|I) = Ɛ(S|F, A) =
+1
+Ns
+t=
+Ɛ(wt | F, A, w<t)
+(1)
+Where F and A represents the feature vector and attribute
+vector respectively. S is the set of words generated by the
+attribute vector F. S= {w1,w2,…wNs} and Ns is the size of
+the set S. I is the actual image.
+The log probability Ɛ(wt | F, A, w<t) is directly proportional
+to the expection of (
+T
+tw
+E (
+t
+vh + b) as shown in Equation
+(2).
+Ɛ(wt |F, A, w <t) ∝ exp (
+T
+tw
+E (
+t
+vh + b)
+(2)
+Where E represents the matrix of the word embeddings, v
+denotes the corresponding matrix while b shows the bais. ht
+is the hidden state. The hidden state calculation is discussed
+in detail in [7].
+
+Semantic validator of caption to image
+As shown in Fig. 1, the semantic redesign of the description
+to picture work to recreate the semantic demonstration of
+every single input image since its comparative captions.
+
+Figure 1: Provides an overview of our proposed model's
+architecture, which
+consists
+of
+three neural
+networks
+(Encoder, Decoder, and Semantic Reconstructor).
+Naturally, a complete semantic reconstructor must meet the
+subsequent dual requirements: On the other
+side, its
+reconstructed presentation must be precise and sufficient to
+replicate image data; on the other side, its use is not
+compiled to have the greatest impact on professionalism. In
+this case, we are referring directly to the caption S that has
+the coverings h = {h1, h2,. . ., hNs} play a significant part in
+the description era. At that point, in this framework, we are
+examining
+three
+semantic
+functions
+to
+determine
+the
+semantic demonstration of the created captions, represented
+by hc, which can help to recreate the reconstituted direction
+of the input image, labeled Ir.
+.
+
+Model Training
+The training set Dtrain = {(F, A, S)}, is used to generate the
+objective function as follows:
+O(D; θed, θdr) = arg max(θed , θdr)
+(I,S)∈D
+{Ɛ(S|I; θed ) +
+�
+λ · R({I1, . . . , IK}|S)}
+(3)
+So we have to maximize the reconstruction score based on
+θed, θdr. θed, θdr represents the encoder and decoder model
+parameters. λ is the hyper-parameters.
+
+Model Testing
+During testing, semantic reconstruction can be utilized to
+improve selected captions. As is it shown in Fig 2, we use a
+multi-stage system that combines beam search and position
+reset. Inserted image captioning techniques:
+Figure 2: A test image of our model. h, P, and R
+show
+the
+hidden
+sequence,
+log
+likelihood
+probability,
+and
+caption
+reconstruction
+score,
+respectively.
+1.
+A collection of applicant captions, log possibilities, and
+unobserved state sequences are generated using the
+standard decoder components via an initial application
+beam investigation.
+2.
+After that, we use the hidden captions of each candidate
+to reconstruct the semantic model of the merged image
+by computing the appropriate reconstructive points.
+
+<cand1,h1.p1>
+<cand2,h2,p2>
+INPUT
+Encoding
+Reconstruction
+Decoding
+Image
+<candk,hk.pk>
+<cand1,p1+gR1>
+<cand2,p2+gR2>
+Caption
+Max
+111
+<candk.pk+gRk>SmallerImage
+DataSet
+Three
+persons
+<aos>
+CNNFeature
+GRU
+GRU
+GRU
+As
+Reconstructed
+Features
+660
+<bos>
+Three
+during
+Caption (S)
+Image (0)
+Image (1)
+Pr(S/l)
+R(1/s)
+LSTM-A5 Model:
+Threepersons standingtogether
+Our Proposed CNN+GRU : Three person standing together on beach during sunset
+Ground Truth:
+Threeperson standingtogether onbeach holding each other
+hand during sunset3.
+After arranging a log and potential school rebuilding
+sites, we calculate the final outcome of each caption
+and select final captions based on the combination of
+points.
+4.
+EXPERIMENTS
+The experiments have been conducted on the most popular
+benchmark dataset COCO [30] to compare the performance
+of our image captioning proposed model with other state-of-
+the-art methods.
+
+Experimental setup
+COCO data-set was used to check the validity of our
+proposed model which contains 130000 manually annotated
+images. Each image has 4 descriptions which were used for
+the training purpose. In addition to this, 5000 images were
+used as testing dataset.
+Out of the 130000 images of the training set, 80000 images
+were used for the training purpose while 5000 images were
+used for the validation purpose. Based on these settings, the
+vocabolary has been built with 8500 unique words. For
+getting the image features, the following setting was used for
+the hyper-paramter tuning.
+Adam [32] is used as the optimizer. We employed stop-
+reading techniques [33] and pre-stop techniques, and we
+determined
+the
+following
+take-out
+hyper-parameter
+parameters: reading level beginning at 2 4, input rate as 300,
+covering layer size as -1024, mini-batch. A maximum cycle
+count of 30 is used with a scale of 1024. We used
+Word2vec's
+[34]
+pre-trained
+embeddings,
+which
+we
+optimized by setting the tradeoff parameter to 1. The
+threshold was established at 3 in our model testing.
+
+Evaluation metrices used:
+The evaluation metrices used are 1) BLEU [40] where we set
+beam size K=3 thus BLEU@1, BLEU@2, BLEU@3 and
+BLEU@4 are calculated. In addition to this, METEOR [46]
+which is shown as M in Table 1, ROUGE-L [37] which is
+shown as R and CIDEr-D [38] which is shown as C in the
+Table1. The values of these metrices were calculated by the
+COCO
+released
+code
+[39].
+BLEU,
+ROUGE-L,
+and
+METEOR were initially developed as benchmarks for
+evaluating the accuracy of machine translation. Image
+caption testing follows the same procedure as machine
+translation testing, where the phrases generated are compared
+to the actual sentences, and metrics are often utilized.
+
+Description of the compared state-of-the-art methods
+1) NIC: The decoder of NIC is based on LSTM which
+directly use features of the images as input to LSTM.
+2) ME: The distinction of this method is its language model
+that explore the mappings bidirectionally in images and their
+captions. This language model is independently built from
+the encoder-decoder framework.
+3) ATT: This model uniquely extracts the key information of
+the images by a model based on semantic attention.
+4) Soft-Attention and Hard Attention (SA and HA) models:
+This model differs from other models in terms of using CNN
+features as input to decoder. The Soft-Attention (SA) is with
+the
+normal
+Back-propagation
+method
+while
+in
+Hard-
+Attention (HA), the stochastic attention is used with re-
+inforcement learning.
+5) LRCN: It is unique in terms of taking the image feature
+and its previous caption as the input at each time-step.
+6) Sentence
+Condition
+(SE):
+In
+this
+method,
+a
+text-
+conditional attention model is used which helps decoder to
+learn the semantic information of the text.
+7) LSTM-A5: This is based on the best variant of LSTM.
+Our propsoed model is inspired by this. We have used the
+same settings of LSTM-A5 for comparison purpose as the
+dataset is also same.
+
+Test results on COCO
+The results got from the experiments by using the COCO
+dataset is shown in the Table 1. As it is obvious from the
+results, our method performed better than all other state-of-
+the-art methods. The results of the metreces BLEU@1,
+BLEU@2, BLEU@3 and BLEU@4 are all better than the
+NIC, HA, SA, ATT, ME, and other compared methods. Even
+on the metrics METEOR [37] which is shown as M in Table
+1, ROUGE-L [38] which is shown as R and CIDEr-D which
+is shown as C in the Table1, which were initially developed
+as benchmarks for evaluating the accuracy of machine
+translation, our resulting indexes are still better on the above
+metrices as compared to NIC, HA, SA, ATT, ME, and other
+compared methods.
+These results proved that the proposed CNN-GRU method
+with semantic validator of caption-to-image is working
+perfectly.
+Table 1: The performance of our proposed model against
+other state-of-the-art methods building VGG framework or
+GoogleNet framework. For clarity, B@K is for BLEU@K
+where K={1,2,3,4}, MET is used for METEOR, ROU is
+represents ROUGE-L, and CID is used for CIDER-D.
+Model
+B@1
+B@2
+B@3
+B@4
+MET
+ROU
+CID
+SA [5]
+0.700
+0.490
+0.322
+0.242
+0.238
+-
+-
+ME [26]
+0.731
+0.559
+0.429
+0.299
+0.246
+0.529
+1.001
+ATT [12]
+0.699
+0.527
+0.399
+0.299
+0.232
+-
+-
+SC [15]
+0.719
+0.540
+0.400
+0.297
+0.239
+-
+0.94
+HA[5]
+0.715
+0.503
+0.355
+0.249
+0.229
+-
+-
+NIC [6]
+0.659
+0.449
+0.399
+0.202
+-
+-
+-
+LRCN
+[41]
+0.690
+0.514
+0.379
+0.270
+0.230
+0.500
+0.830
+LSTM-
+A5
+0.729
+0.559
+0.429
+0.325
+0.253
+0.539
+1.002
+Proposed
+CNN+G
+RU
+0.751
+0.578
+0.439
+0.335
+0.259
+0.545
+1.035
+
+Test results on COCO's online test server
+Table 2: Performance comparisons on online COCO
+test server (C40). MS Captivator is a photo caption
+model suggested by Fang et al. [27].
+Model
+B@1
+B@2
+B@3
+B@4
+MET
+ROU
+CID
+SA [5]
+0.721
+0.494
+0.333
+0.251
+0.242
+0.511
+0.98
+ME [26]
+0.743
+0.561
+0.432
+0.293
+0.251
+0.534
+1.013
+ATT [12]
+0.691
+0.532
+0.393
+0.287
+0.242
+-
+-
+SC [15]
+0.729
+0.544
+0.412
+0.281
+0.241
+0.511
+0.92
+HA[5]
+0.725
+0.512
+0.358
+0.253
+0.231
+-
+-
+NIC [6]
+0.669
+0.456
+0.382
+0.218
+0.232
+-
+-
+LRCN [41]
+0.698
+0.521
+0.382
+0.281
+0.241
+0.512
+0.812
+LSTM-A5
+0.731
+0.562
+0.432
+0.331
+0.258
+0.542
+1.000
+Proposed
+0.742
+0.583
+0.441
+0.339
+0.263
+0.556
+1.012
+
+CNN+GRU
+Table 3: Performance comparisons on online COCO
+test server (C40). MS Captivator is a photo caption
+model suggested by Fang et al. [27].
+Model
+B@1
+B@2
+B@3
+B@4
+MET
+ROU
+CID
+SA [5]
+0.898
+0.800
+0.605
+0.505
+0.347
+0.686
+0.940
+ME [26]
+0.900
+0.781
+0.701
+0.575
+0.340
+0.685
+0.864
+ATT [12]
+0.897
+0.825
+0.605
+0.505
+0.345
+0.680
+0.928
+SC [15]
+0.900
+0.808
+0.705
+0.505
+0.343
+0.685
+0.919
+HA[5]
+0.899
+0.804
+0.622
+0.515
+0.345
+0.682
+0.940
+NIC [6]
+0.901
+0.809
+0.711
+0.510
+0.337
+0.680
+0.952
+LRCN [41]
+0.902
+0.814
+0.710
+0.512
+0.339
+0.680
+0.947
+LSTM-A5
+0.903
+0.816
+0.702
+0.602
+0.338
+0.686
+0.964
+Proposed
+CNN+GRU
+0.904
+0.818
+0.712
+0.603
+0.343
+0.687
+0.967
+To further confirm the validity of our model, the COCO's
+online test server was used to evaluate the performance on
+the test set. In particular, the captions made by proposed
+CNN-GRU
+were
+uploaded
+to
+the
+server
+to
+do
+the
+comparisons with the baseline models. The official test
+images, 5 (c5) reference captions, and 40 (c40) reference
+captions used in Table 2 and Table 3 are shown. It is clearly
+seen again on the results that our method outperformed all
+other state-of-the-art methods. The results of the metreces
+BLEU@1, BLEU@2, BLEU@3 and BLEU@4 are all better
+than the NIC, HA, SA, ATT, ME, and other compared
+methods. Even on the metrics METEOR which is shown as
+M in Table 2 and Table 3, ROUGE-L which is shown as R
+and CIDEr-D which is shown as C in the Table 2 and Table
+3, which were initially developed as benchmarks for
+evaluating the accuracy of machine translation, our resulting
+indexes are still better on the above metrices as compared to
+NIC, HA, SA, ATT, ME, and other compared methods.
+Fig.3 Model performance with different K.
+5.
+CONCLUSION AND FUTURE WORK
+In this paper, we have proposed CNN-GRU based hybrid
+deep learning model with better hyper-parameter tuning to
+do image captioning. Our CNN-GRU encoder decode
+framework do caption-to-image reconstruction to handle the
+semantic context into consideration as well as the time
+complexity. By taking the hidden states of the decoder into
+consideration, the input image and its similar semantic
+representations were reconstructed and reconstruction scores
+from a semantic reconstructor were used in conjunction with
+likelihood during model training to assess the quality of the
+generated
+caption. As
+a
+result, the
+decoder
+received
+improved semantic information, enhancing the caption
+production process. During model testing, combining the
+reconstruction score and the log-likelihood was also feasible
+to choose the most appropriate caption. The suggested model
+outperforms the state-of-the-art LSTM-A5 model for picture
+captioning in terms of time complexity and accuracy.
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+
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+page_content='00 ©20XX IEEE  An Image captioning algorithm based on the Hybrid Deep Learning  Technique (CNN+GRU)  Rana Adnan Ahmad  Department of Computer Science  Comsats university islamabad, sahiwal  campus,Sahiwal,Pakistan  rana22293@gmail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='com  Muhammad Azhar  Department of computer science  Comsats university islamabad, sahiwal  campus,Sahiwal,Pakistan  azhar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='cs@cuisahiwal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='pk  Chosun University, Republic of Korea  Muhammad.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='azhar@chosun.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='ac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='kr  Hina Sattar  Department of computer science  Comsats university islamabad, sahiwal  campus, Sahiwal, Pakistann  hinasattar987@gmail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='com  Abstract—  Image  captioning  by  the  encoder-decoder  framework has shown tremendous advancement in the last  decade where CNN is mainly used as encoder and LSTM is  used as a decoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Despite such an impressive achievement in  terms of accuracy in simple images, it lacks in terms of time  complexity and space complexity efficiency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In addition to this,  in case of complex images with a lot of information and objects,  the  performance  of  this  CNN-LSTM  pair  downgraded  exponentially due to the lack of semantic understanding of the  scenes presented in the images.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Thus, to take these issues into  consideration,  we  present  CNN-GRU  encoder  decode  framework for caption-to-image reconstructor to handle the  semantic context into consideration as well as the time  complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' By taking the hidden states of the decoder into  consideration, the input image and its similar semantic  representations is reconstructed and reconstruction scores  from a semantic reconstructor are used in conjunction with  likelihood during model training to assess the quality of the  generated caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' As a result, the decoder receives improved  semantic  information,  enhancing  the  caption  production  process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' During model testing, combining the reconstruction  score and the log-likelihood is also feasible to choose the most  appropriate caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The suggested model outperforms the  state-of-the-art LSTM-A5 model for picture captioning in  terms of time complexity and accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Index Terms— Deep Learning, Image captioning, CNN, GRU  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  INTRODUCTION  Deep Learning has made great strides recently due to rapid  growth and high utilization [1-4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Thus, similar to Neural  Machine Translation (NMT)[5], generating captions of the  images through neural encoder-decoder framework has  shown the dominance in recent years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In this process of  image captioning, encoding of the image is done through  encoder which is typically from the Convolutional Neural  Networks (CNN) [6] family (like Vanilla CNN [6], Region  based CNN [7], Fast R-CNN [8], Faster R-CNN [9] etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=') and  decoder is from the RNN family [10] (like LSTM [11],  BLSTM [12] etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=').' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In this framework of CNN-LSTM pair  [13-16], the encoder (CNN) learns the visual features by  making the feature maps and max-pooling during the feature  learning stage and then detection of objects after flattening  and applying fully connected layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Thus it converts the  image to vector of numbers which is learned form of the  visual content of the image under consideration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In the  decoder part, the vector output of the encoder is used as the  initial input of the decoder to produce caption word by word.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Even though Long Short Term Memory (LSTM) solves the  issue of handling long dependency by decreasing the effect  of  exploding  and  vanishing  gradients  [11],  the  time  complexity issue is still a major drawback in this model due  to  many  gates  residing  in  the  LSTM  unit  for  the  memorization purpose.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Another key issue with these kind of  encoder-decoder models are the lack of understanding of the  semantic context as the encoder of these models fail to  transfer the major key visual information to the decoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Because of the absence of reverse dependency checking  (Caption-to-Image), these models do not perform well in  case of complex images.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Several approaches have been proposed to deal with the  above-mentioned issues [17-20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Some researches have  proposed the attention mechanism to get the information  from the key regions automatically and tried to encode that  specific information into the context vector which then used  by the decoder to generate the caption [17,18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Some other  researchers have tried to extract semantic attributes as a  supplement of the CNN features to embed into encoder by  various methods [19, 20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  The major drawback of all the above mentioned methods  was that those methods only explore the image-to-caption  dependency but not the reverse way for the validation of the  extracted information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Even though, Jinsong Su et.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='el.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' [21]  have tried to use the semantic reconstructor of caption-to-  image but still they could not  validated the results in  effective way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In addition to this, the time complexity issue  was also remained due to the usage of LSTM unit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  To resolve the above mentioned issues, we have proposed a  hybrid deep learning technique based on the CNN-GRU  encoder-decoder gramework with the better hyper-parameter  tuning and with the caption-to-image validation method by  taking the motivation from Jinsong Su et.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='el.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' This  caption-to-image reconstructor helps to handle the semantic  context into consideration as well as the time complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' By  taking the hidden states of the decoder into consideration, the  input image and its similar semantic representations is  reconstructed and reconstruction scores from a semantic  reconstructor are used in conjunction with likelihood during  model training to assess the quality of the generated caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  As a result, the decoder receives improved semantic  information, enhancing the caption production process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  During model testing, combining the reconstruction score  and the log-likelihood is also feasible to choose the most  appropriate caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  To validate our proposed method, we have used the  benchmark MS COCO dataset [22] and the experimental  results have proved that our method outperformed the current  state-of-the-art methods in terms of accuracy and time  complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  RELATED WORK  Inspiration for our work comes from the auto encoder [23,24]  and how well it performs in NMT [25], which employs  semantic production to hone the learning representation of  input data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In this activity, we are fine-tuning the idea with  captions to the image.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Basically, related work involves  taking after two strands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=" In general, NMT's common hands  are very much based on the demonstration of source-to-target  interpretation." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Encouraged by questions about the auto  encoder that makes reproduction more realistic and looking  at whether the recreated inputs are more reliable than the  original inputs [26], many analysts are committed to using  the adaptation of dual-directed NMT conditions [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Compared with NMT, most models of neural image captions  are based on the neural encoder-decoder system [30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  However, this engineer cannot guarantee that the image data  can be completely converted into a decoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' To discuss this  problem, analysts are currently accepting to take after two  types of approaches: (1) As in NMT attention [31], a few  analysts link part of the visual considerations to capture the  semantic presentations of critical image regions [32,33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' (2)  In various ways, a number of analysts are committed to  extract semantic features or high-level concepts into images,  which can be integrated into an LSTM-based decoder as an  additional input [28,29].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In this way, the show will be  directed to settings that are closely related to the theme of the  image.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Besides, You et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' [34] encompassed the two types  of methods listed above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Our proposed representation is based on the CNN-LSTM  model, in which the proposed semantic reconstructor is  comparably compared to the LSTM, which is why it benefits  both to display preparation and testing when the regional  language indicate and the coding system are modeled  independently.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' From Wena et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' [35] Institution devoted to  improving  automatically  generated  image  captions  by  making inferences about their semantic content.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' However,  the visual highlights are generally employed as the decode of  the decoder in the current model captions, while the semantic  elements of the image are provided exclusively to the  decoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' As a result, we agree that visual robustness is more  crucial than semantic characteristics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Through this research,  we provide semantic features to neural machine translation  as  well  as  video  captions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  In  conclusion,  we  are  experimenting  with  three  different  methods  for  reconstructing  photos  based  on  fabricated  captions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content="  Additionally, our claim may be distinct from earlier studies  due to K's extensive utilization of visually similar photos." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  PROPOSED MODEL  This section describes the proposed hybrid deep learning  approach based on CNN-GRU encoder-decoder framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  This framework has 3 major parts, 1) Encoder: which is the  CNN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' 2) Decoder: which is the GRU layer and 3) The  Semantic validator: for validation of the caption-to-image  information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Model architecture  The three neural network modules (Encoder, Decoder, and  Semantic validator) that make up our proposed model are  depicted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The details of each module is given below:  \uf06c  Encoder  In encoder, a model similar to [36] has been used where the  image I is taken as input and the features from the image F is  extracted by the CNN-based encoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The feature vector F  ∈ RDv is used to represent the features extracted from the  image I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Dv represents the diemnsions of the feature vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  As all the sementic information can not be extracted by one  feature vector, thus additional semantic attributes have been  extracted by the algorithm proposed by Yao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' [36].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The  extracted attribute vector is denoted by A ∈ RDa which  shows the probabilty of each high level attribute existed in  the caption dataset which is generated by the MIL (Multiple  Instance Learning) model presented in [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' MIL model  showed the promising results in finding the semantic  relations between the attributes of the image.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Da represents  the diemnsions of the attribute vector A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  After extracting both feature map F and attribute vector A,  the encoder gives these 2 outputs to decoder as an input  which is used for the caption generation purpose.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Decoder  As we got feature vector F and the attribute vector A as an  output of the encoder from previous network, this F and A is  used as the input to the decoder for the caption generation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Yao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' [36] proposes 5 different and diverse variants for  the LSTM network and it is proved that the fifth one named  LSTM-A5 works better than others, so we also used the same  network for getting the better performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Thus, according  to LSTM-A5, we used the A and F vectors to calculate the log  Probability Ɛ as mentioned in Equation (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Ɛ(S|I) = Ɛ(S|F, A) =  1  Ns  t=  Ɛ(wt | F, A, w<t)  (1)  Where F and A represents the feature vector and attribute  vector respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' S is the set of words generated by the  attribute vector F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' S= {w1,w2,…wNs} and Ns is the size of  the set S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' I is the actual image.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  The log probability Ɛ(wt | F, A, w<t) is directly proportional  to the expection of (  T  tw  E (  t  vh + b) as shown in Equation  (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Ɛ(wt |F, A, w <t) ∝ exp (  T  tw  E (  t  vh + b)  (2)  Where E represents the matrix of the word embeddings, v  denotes the corresponding matrix while b shows the bais.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' ht  is the hidden state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The hidden state calculation is discussed  in detail in [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Semantic validator of caption to image  As shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' 1, the semantic redesign of the description  to picture work to recreate the semantic demonstration of  every single input image since its comparative captions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content="  Figure 1: Provides an overview of our proposed model's  architecture, which  consists  of  three neural  networks  (Encoder, Decoder, and Semantic Reconstructor)." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Naturally, a complete semantic reconstructor must meet the  subsequent dual requirements: On the other  side, its  reconstructed presentation must be precise and sufficient to  replicate image data;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' on the other side, its use is not  compiled to have the greatest impact on professionalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In  this case, we are referring directly to the caption S that has  the coverings h = {h1, h2,.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', hNs} play a significant part in  the description era.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' At that point, in this framework, we are  examining  three  semantic  functions  to  determine  the  semantic demonstration of the created captions, represented  by hc, which can help to recreate the reconstituted direction  of the input image, labeled Ir.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Model Training  The training set Dtrain = {(F, A, S)}, is used to generate the  objective function as follows:  O(D;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' θed, θdr) = arg max(θed , θdr)  (I,S)∈D  {Ɛ(S|I;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' θed ) +  �  λ · R({I1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' , IK}|S)}  (3)  So we have to maximize the reconstruction score based on  θed, θdr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' θed, θdr represents the encoder and decoder model  parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' λ is the hyper-parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Model Testing  During testing, semantic reconstruction can be utilized to  improve selected captions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' As is it shown in Fig 2, we use a  multi-stage system that combines beam search and position  reset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Inserted image captioning techniques:  Figure 2: A test image of our model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' h, P, and R  show  the  hidden  sequence,  log  likelihood  probability,  and  caption  reconstruction  score,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  A collection of applicant captions, log possibilities, and  unobserved state sequences are generated using the  standard decoder components via an initial application  beam investigation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  After that, we use the hidden captions of each candidate  to reconstruct the semantic model of the merged image  by computing the appropriate reconstructive points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  <cand1,h1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='p1>  <cand2,h2,p2>  INPUT  Encoding  Reconstruction  Decoding  Image  <candk,hk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='pk>  <cand1,p1+gR1>  <cand2,p2+gR2>  Caption  Max  111  <candk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='pk+gRk>SmallerImage  DataSet  Three  persons  <aos>  CNNFeature  GRU  GRU  GRU  As  Reconstructed  Features  660  <bos>  Three  during  Caption (S)  Image (0)  Image (1)  Pr(S/l)  R(1/s)  LSTM-A5 Model:  Threepersons standingtogether  Our Proposed CNN+GRU : Three person standing together on beach during sunset  Ground Truth:  Threeperson standingtogether onbeach holding each other  hand during sunset3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  After arranging a log and potential school rebuilding  sites, we calculate the final outcome of each caption  and select final captions based on the combination of  points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  EXPERIMENTS  The experiments have been conducted on the most popular  benchmark dataset COCO [30] to compare the performance  of our image captioning proposed model with other state-of-  the-art methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Experimental setup  COCO data-set was used to check the validity of our  proposed model which contains 130000 manually annotated  images.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Each image has 4 descriptions which were used for  the training purpose.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In addition to this, 5000 images were  used as testing dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Out of the 130000 images of the training set, 80000 images  were used for the training purpose while 5000 images were  used for the validation purpose.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Based on these settings, the  vocabolary has been built with 8500 unique words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' For  getting the image features, the following setting was used for  the hyper-paramter tuning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Adam [32] is used as the optimizer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' We employed stop-  reading techniques [33] and pre-stop techniques, and we  determined  the  following  take-out  hyper-parameter  parameters: reading level beginning at 2 4, input rate as 300,  covering layer size as -1024, mini-batch.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' A maximum cycle  count of 30 is used with a scale of 1024.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=" We used  Word2vec's  [34]  pre-trained  embeddings,  which  we  optimized by setting the tradeoff parameter to 1." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The  threshold was established at 3 in our model testing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Evaluation metrices used:  The evaluation metrices used are 1) BLEU [40] where we set  beam size K=3 thus BLEU@1, BLEU@2, BLEU@3 and  BLEU@4 are calculated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In addition to this, METEOR [46]  which is shown as M in Table 1, ROUGE-L [37] which is  shown as R and CIDEr-D [38] which is shown as C in the  Table1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The values of these metrices were calculated by the  COCO  released  code  [39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  BLEU,  ROUGE-L,  and  METEOR were initially developed as benchmarks for  evaluating the accuracy of machine translation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Image  caption testing follows the same procedure as machine  translation testing, where the phrases generated are compared  to the actual sentences, and metrics are often utilized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Description of the compared state-of-the-art methods  1) NIC: The decoder of NIC is based on LSTM which  directly use features of the images as input to LSTM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  2) ME: The distinction of this method is its language model  that explore the mappings bidirectionally in images and their  captions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' This language model is independently built from  the encoder-decoder framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  3) ATT: This model uniquely extracts the key information of  the images by a model based on semantic attention.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  4) Soft-Attention and Hard Attention (SA and HA) models:  This model differs from other models in terms of using CNN  features as input to decoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The Soft-Attention (SA) is with  the  normal  Back-propagation  method  while  in  Hard-  Attention (HA), the stochastic attention is used with re-  inforcement learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  5) LRCN: It is unique in terms of taking the image feature  and its previous caption as the input at each time-step.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  6) Sentence  Condition  (SE):  In  this  method,  a  text-  conditional attention model is used which helps decoder to  learn the semantic information of the text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  7) LSTM-A5: This is based on the best variant of LSTM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Our propsoed model is inspired by this.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' We have used the  same settings of LSTM-A5 for comparison purpose as the  dataset is also same.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  \uf06c  Test results on COCO  The results got from the experiments by using the COCO  dataset is shown in the Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' As it is obvious from the  results, our method performed better than all other state-of-  the-art methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The results of the metreces BLEU@1,  BLEU@2, BLEU@3 and BLEU@4 are all better than the  NIC, HA, SA, ATT, ME, and other compared methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Even  on the metrics METEOR [37] which is shown as M in Table  1, ROUGE-L [38] which is shown as R and CIDEr-D which  is shown as C in the Table1, which were initially developed  as benchmarks for evaluating the accuracy of machine  translation, our resulting indexes are still better on the above  metrices as compared to NIC, HA, SA, ATT, ME, and other  compared methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  These results proved that the proposed CNN-GRU method  with semantic validator of caption-to-image is working  perfectly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Table 1: The performance of our proposed model against  other state-of-the-art methods building VGG framework or  GoogleNet framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' For clarity, B@K is for BLEU@K  where K={1,2,3,4}, MET is used for METEOR, ROU is  represents ROUGE-L, and CID is used for CIDER-D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content="967  To further confirm the validity of our model, the COCO's  online test server was used to evaluate the performance on  the test set." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In particular, the captions made by proposed  CNN-GRU  were  uploaded  to  the  server  to  do  the  comparisons with the baseline models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The official test  images, 5 (c5) reference captions, and 40 (c40) reference  captions used in Table 2 and Table 3 are shown.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' It is clearly  seen again on the results that our method outperformed all  other state-of-the-art methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The results of the metreces  BLEU@1, BLEU@2, BLEU@3 and BLEU@4 are all better  than the NIC, HA, SA, ATT, ME, and other compared  methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Even on the metrics METEOR which is shown as  M in Table 2 and Table 3, ROUGE-L which is shown as R  and CIDEr-D which is shown as C in the Table 2 and Table  3, which were initially developed as benchmarks for  evaluating the accuracy of machine translation, our resulting  indexes are still better on the above metrices as compared to  NIC, HA, SA, ATT, ME, and other compared methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='3 Model performance with different K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  CONCLUSION AND FUTURE WORK  In this paper, we have proposed CNN-GRU based hybrid  deep learning model with better hyper-parameter tuning to  do image captioning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Our CNN-GRU encoder decode  framework do caption-to-image reconstruction to handle the  semantic context into consideration as well as the time  complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' By taking the hidden states of the decoder into  consideration, the input image and its similar semantic  representations were reconstructed and reconstruction scores  from a semantic reconstructor were used in conjunction with  likelihood during model training to assess the quality of the  generated  caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' As  a  result, the  decoder  received  improved semantic information, enhancing the caption  production process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' During model testing, combining the  reconstruction score and the log-likelihood was also feasible  to choose the most appropriate caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' The suggested model  outperforms the state-of-the-art LSTM-A5 model for picture  captioning in terms of time complexity and accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  REFERENCES  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Alahmadi, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', & Hahn, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' (2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Improve Image  Captioning by Estimating the Gazing Patterns from the  Caption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In Proceedings of the IEEE/CVF Winter  Conference on Applications of Computer Vision (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  Wei, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', Li, Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', Zhu, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', & Ma, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=', Li, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' Aligned visual  semantic  scene  graph  for  image  captioning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  Medical Image Captioning Using Optimized Deep  Learning  Model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Computational  Intelligence  and  Neuroscience, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' Faster r-  cnn: Towards real-time object detection with region  proposal networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' Multi-Branch Distance-Sensitive  Self-Attention Network for Image Captioning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' IEEE  Transactions on Multimedia.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  Wang, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' Vatex: A large-scale, high-quality  multilingual dataset for video-and-language research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  In  Proceedings  of  the  IEEE/CVF  International  Conference on Computer Vision (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  In Proceedings of the IEEE conference on computer  vision and pattern recognition (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' (2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  In Proceedings of the IEEE conference on computer  vision and pattern recognition (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' 311-318).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  Banerjee, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' METEOR: An  automatic metric for MT evaluation with improved  correlation with human judgments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' (2004, July).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Rouge: A package for  automatic  evaluation  of  summaries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  In  Text  summarization branches out (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Vedantam, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content='  (2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Cider:  Consensus-based  image  description  evaluation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' In Proceedings of the IEEE conference on  computer vision and pattern recognition (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' 4566-  4575).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='  Chen, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', Fang, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', Lin, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=', Vedantam, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=', Gupta, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=',  Dollár, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+page_content=' (2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' Microsoft coco  captions: Data collection and evaluation server.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content=' arXiv  preprint arXiv:1504.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
+page_content='00325.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/I9E0T4oBgHgl3EQfiAGs/content/2301.02440v1.pdf'}
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf,len=978
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='12021v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='NT]  27 Jan 2023  THE QUOTIENT SET OF THE QUADRATIC DISTANCE SET OVER FINITE FIELDS  ALEX IOSEVICH, DOOWON KOH, AND FIRDAVS RAKHMONOV  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let Fd  q be the d-dimensional vector space over the finite field Fq with q elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  For each  non-zero r in Fq and E ⊂ Fd  q, we define W (r) as the number of quadruples (x, y, z, w) ∈ E4 such that  Q(x − y)/Q(z − w) = r, where Q is a non-degenerate quadratic form in d variables over Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' When Q(α) =  �d  i=1 α2  i with α = (α1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , αd) ∈ Fd  q, Pham (2022) recently used the machinery of group actions and proved  that if E ⊂ F2  q with q ≡ 3 (mod 4) and |E| ≥ Cq, then we have W (r) ≥ c|E|4/q for any non-zero square  number r ∈ Fq, where C is a sufficiently large constant, c is some number between 0 and 1, and |E| denotes  the cardinality of the set E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In this article, we improve and extend Pham’s result in two dimensions to arbitrary dimensions with  general non-degenerate quadratic distances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As a corollary of our results, we also generalize the sharp  results on the Falconer type problem for the quotient set of distance set due to the first two authors and  Parshall (2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Furthermore, we provide improved constants for the size conditions of the underlying sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The key new ingredient is to relate the estimate of the W (r) to a quadratic homogeneous variety in  2d-dimensional vector space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' This approach is fruitful because it allows us to take advantage of Gauss sums  which are more handleable than the Kloosterman sums appearing in the standard distance type problems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Introduction  Let Fd  q, d ≥ 2, be the d-dimensional vector space over the finite field Fq with q elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Throughout this  paper, we assume that q is a power of odd prime p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Given a set E in Fd  q, the distance set ∆(E) is defined by  ∆(E) := {||x − y|| ∈ Fq : x, y ∈ E},  where ||α|| = �d  i=1 α2  i for α = (α1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , αd) ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In the finite field setting, the Falconer distance problem asks for the minimal exponent α > 0 such that  for any subset E of Fd  q with |E| ≥ Cqα, we have |∆(E)| ≥ cq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Here, and throughout this paper, C > 1  denotes a sufficiently large constant, and 0 < c ≤ 1 denotes some constant independent of q and |E|, where  |E| denotes the cardinality of E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' This problem was initially proposed by the first listed author and Rudnev  [20] as a finite field analogue of the Falconer distance problem in the Euclidean space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We notice that the  formulation of the finite field Falconer problem was also motivated on the Erd˝os distinct distances problem  over finite fields due to Bourgain, Katz and Tao [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, the problem is also called the Erd˝os-Falconer  distance problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We refer readers to [13, 18, 34, 16, 14, 15, 11, 12, 10] for precise definition, background  knowledge, and recent progress on the Erd˝os distinct distances problem and the Falconer distance problem  in the Euclidean setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As a strong version of the Erd˝os-Falconer distance problem, one can consider the Mattila-Sj¨olin distance  problem over finite fields which is to determine the smallest threshold β > 0 such that any subset E of Fd  q  with |E| ≥ Cqβ generates all possible distances, namely, ∆(E) = Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Using Fourier analytic machinery and  the Kloosterman sum estimate, the first listed author and Rudnev obtained the threshold (d + 1)/2 for all  dimensions d ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (Iosevich and Rudnev, [20]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that E ⊂ Fd  q, d ≥ 2, and |E| > 2q(d+1)/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we have  ∆(E) = Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The threshold (d + 1)/2 in Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 is the best currently known result on the Mattila-Sj¨olin distance  problem over finite fields for all dimensions d ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' It is considered as an extremely hard problem to improve  2010 Mathematics Subject Classification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' 52C10, 42B05, 11T23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Key words and phrases: Finite field, Quadratic distance, Quotient set  The research of the first listed author was supported in part by the National Science Foundation under grant no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' HDR TRIPODS  1934962 and by the NSF DMS-2154232.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The second listed author was supported by Basic Science Research Programs through  National Research Foundation of Korea (NRF) funded by the Ministry of Education (NRF-2018R1D1A1B07044469).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  1  the (d+1)/2 result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Moreover, in the general setting of odd dimensions, it gives the optimal threshold, which  was proven in [19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  However, in even dimensions, it has been believed that the exponent (d + 1)/2 can be improved but a  reasonable evidence or conjecture has not been stated in literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In two dimensions, Murphy and Petridis  [27] showed that the threshold cannot be lower than 4/3 for the Mattila-Sj¨olin distance problem over finite  fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  On the other hand, the first listed author and Rudnev [20] conjectured that the threshold (d + 1)/2 can  be lower to d/2 for the Erd˝os-Falconer distance problem in even dimensions, and in two dimensions the  threshold 4/3 was proven by the authors in [6] (see also [3]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Furthermore, when q is prime, the exponent  4/3 was improved to 5/4 by Murphy, Petridis, Pham, Rudnev, and Stevenson [28].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We also notice that the  threshold (d + 1)/2 cannot be improved for the Erd˝os-Falconer distance problem in general odd dimensions  (see also [19]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The distance problems over finite fields have been extended in various directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For example, Shparlinski  [32] studied the size of the distance set between two sets in Fd  q (see also [23, 25]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The generalized distance  problems with polynomial distances were investigated by the second listed author and Shen [24] and Vinh  [36].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Covert, the second listed author, and Pi [8] studied the size of the k-distance set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Hart and the  first listed author [9] extended the distance problem to the k-simplices problem over finite fields (see also  [2, 4, 29, 31, 35]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Shparlinski [33] addressed the Erd˝os-Falconer distance problem for the sum of the distance  set, namely ∆(E) + ∆(E) (see also [7, 22]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Although lots of variants of the distance problems were extensively studied, the threshold d/2 for the set  E in Fd  q had not been addressed for any distance type problems until the first two authors and Parshall [21]  studied the following Mattila-Sj˝olin problem for the quotient set of the distance set over finite fields:  Problem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 (The Mattila-Sj˝olin problem for the quotient set of the distance set).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Given a set E in  Fd  q, d ≥ 2, the quotient set of the distance set, denoted by ∆(E)  ∆(E), is defined by  ∆(E)  ∆(E) :=  � ||x − y||  ||z − w|| : x, y, z, w ∈ E, ||z − w|| ̸= 0  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Determine the smallest exponent γ > 0 such that, for any set E ⊂ Fd  q with |E| ≥ Cqγ, we have  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1)  ∆(E)  ∆(E) = Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The aforementioned authors obtained the threshold d/2 in even dimensions on the Mattila-Sj˝olin problem  for the quotient set of the distance set over finite fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' More precisely, they proved the following result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 (Theorems 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2, [21]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let E ⊂ Fd  q, d ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then the following statements hold:  (i) If d ≥ 2 is even and |E| ≥ 9qd/2, then ∆(E)  ∆(E) = Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d ≥ 3 is odd and |E| ≥ 6qd/2, then ∆(E)  ∆(E) ⊇ (Fq)2, where (Fq)2 := {a2 : a ∈ Fq}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We shall write F∗  q for the set of all non-zero elements in Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As the main idea to deduce Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3, the authors [21] first observed that for any r ∈ F∗  q, we have  r ∈ ∆(E)  ∆(E)  if  �  t∈Fq  v(t)v(rt) > v2(0),  where v(t) is the number of the pairs (x, y) ∈ E × E such that ||x − y|| = t, namely,  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2)  v(t) :=  �  x,y∈E:  ||x−y||=t  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Next, using the discrete Fourier analysis, they estimated a lower bound of �  t∈Fq v(t)v(rt) and an upper  bound of v2(0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Finally, the required size condition on the sets E was obtained by comparing them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Although  the method of the proof led to the optimal threshold result on the Mattila-Sj¨olin problem for the quotient  set of the distance set, it has two drawbacks below, as mentioned by Pham [30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  2  The proof is too sophisticated and it requires large amount of calculation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  It is not clear from the proof that how many quadruples (x, y, z, w) ∈ E4 contribute to producing  each element r ∈ F∗  q such that ||x−y||  ||z−w|| = r, namely, r ∈ ∆(E)  ∆(E).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As a way to overcome the above issues, Pham [30] utilized the machinery of group actions in two dimensions  and obtained a lower bound of V (r) for any square number r in F∗  q, where V (r) denotes the number of the  quadruples (x, y, z, w) ∈ E4 such that ||x−y||  ||z−w|| = r, namely,  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3)  V (r) :=  �  x,y,z,w∈E:  ||x−y||  ||z−w|| =r  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As a consequence, he provided a short proof to deduce the following lower bound of V (r) in two dimensions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 (Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2, [30]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let E be a subset of F2  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that |E| ≥ Cq with q ≡ 3 (mod 4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then, for any non-zero square number r in F∗  q, we have  V (r) ≥ c|E|4  q  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In particular, we have ∆(E)  ∆(E) ⊇ (Fq)2 := {a2 : a ∈ Fq}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Pham’s approach, based on the group action, is powerful in the sense that it gives a simple proof and an  information about a lower bound of V (r).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' However, his result, Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4, is limited to two dimensions  with −1 square in Fq, and it gives us no information about V (r) for a non-square r in F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  One of the main contributions of this paper is to improve and extend Pham’s result to all dimensions  for arbitrary finite fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In particular, we will work on the problem with the non-degenerate quadratic  distances which generalize the usual distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The other contribution is to provide significantly improved explicit constants for size conditions on the  underlying sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' These are mainly based on our approach to view the problem for the set E in Fd  q as that for  the product set E × E associated with certain homogeneous variety of degree two in F2d  q  (see Section 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' As  a direct consequence of this method, we will also address a generalized version of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3, with more  accurate constants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  To precisely state our main results, let us set up some definitions and notations related to the quadratic  distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Definition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5 (Non-degenerate quadratic form).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We identify a vector x = (x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd) ∈ Fd  q with a  d × 1 matrix over Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' A non-degenerate quadratic form Q(x) is a homogeneous polynomial of degree 2  in Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd], and is written by Q(x) = x⊤A x =  d�  i,j=1  aijxixj for some d × d symmetric matrix A = [aij]  with det(A) ̸= 0, where x⊤ denotes the transpose of the column vector x and each entry aij of A belongs to  Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Note that if A is the identity matrix, then Q(x) = ||x||.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, Q(x) generalizes the distance function  || · ||.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For E ⊂ Fd  q, the non-degenerate quadratic distance set ∆Q(E) is defined by  ∆Q(E) := {Q(x − y) : x, y ∈ E} ⊂ Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The quotient set of the quadratic distance set ∆Q(E) is defined as  ∆Q(E)  ∆Q(E) :=  � b  a ∈ Fq : a, b ∈ ∆Q(E), a ̸= 0  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  For r ∈ F∗  q, and E ⊂ Fd  q, define W(r) as the number of quadruples (x, y, z, w) ∈ E4 such that Q(x−y)  Q(z−w) = r,  namely,  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4)  W(r) :=  �  x,y,z,w∈E:  Q(x−y)  Q(z−w) =r  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Our main result is as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  3  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For E ⊂ Fd  q, d ≥ 2, let W(r) be defined as in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (i) If d is even and |E| ≥ 4q  d  2 , then W(r) ≥ 5|E|4  48q  for all r in F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Moreover, the threshold d/2 is sharp  for any finite field Fq and all even dimensions d ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d is odd and |E| ≥ 3q  d  2 , then W(r) ≥ 2|E|4  45q  for all non-zero square numbers r in F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Furthermore,  the threshold d/2 cannot be lower for any finite field Fq and all odd dimensions d ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (iii) If d is odd and |E| ≥ 11  6 q  d+1  2 , then W(r) ≥ 2|E|4  363q for all r in F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In addition, the threshold (d+1)/2  cannot be improved for any finite field Fq and all odd dimensions d ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As a consequence of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6, we generalize Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 with accurate constants improved for the  cardinality of sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Corollary 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let E ⊂ Fd  q, d ≥ 2, and Q ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd] be a non-degenerate quadratic form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then the  following statements are valid:  (i) If d is even and |E| ≥ 4qd/2, then ∆Q(E)  ∆Q(E) = Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Moreover, the exponent d/2 cannot be improved for  arbitrary finite field Fq and all even dimensions d ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d is odd and |E| ≥ 3qd/2, then ∆Q(E)  ∆Q(E) ⊇ (Fq)2, where (Fq)2 := {a2 : a ∈ Fq}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In addition, the  exponent d/2 is optimal for arbitrary finite field Fq and all odd dimensions d ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (iii) If d is odd and |E| ≥ 11  6 q(d+1)/2, then ∆Q(E)  ∆Q(E) = Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Furthermore, the threshold (d + 1)/2 cannot be  lower for any finite field Fq and all odd dimensions d ≥ 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We claim that the statements (i), (ii), (iii) of the corollary directly follow from those (i), (ii),(iii) of  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' To prove our claim, first observe that if r ∈ F∗  q, then W(r) > 0 if and only if  r ∈ ∆Q(E)  ∆Q(E).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Combining this observation with Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (i), (ii), (iii), the proof of the corollary is reduced to  showing that 0 ∈ ∆Q(E)  ∆Q(E) under each assumption of Corollary (i), (ii), (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since r ∈ ∆Q(E)  ∆Q(E) for some non-zero  r in F∗  q, we can choose x, y, z, w in E such that Q(x− y) ̸= 0 and Q(z − w) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, 0 = Q(x−x)  Q(z−w) ∈ ∆Q(E)  ∆Q(E),  as required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  □  We have the following few comments on our results, Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 and Corollary 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The results on Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 and Corollary 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7 are independent of the choice of non-degenerate qua-  dratic forms Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (i) improves and extends Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 to all even dimensions and arbitrary finite fields  with the general non-degenerate quadratic distances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For instance, the theorem holds true and sharp  without any further assumption such as the condition q ≡ 3 (mod 4), which was necessary in proving  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 by using the group actions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In addition, our theorem provides explicit constants with  small numbers, which are based on our different approaches to estimate the counting functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Corollary 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7 (i), (ii) clearly generalize Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 (i), (ii), respectively, with the improved con-  stants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Notice that when Q(x) = ||x||, the usual distance, the threshold (d + 1)/2 in Corollary 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7  (iii) follows immediately from Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' However, the constant 11/6 for the set size in Corollary  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7 cannot be obtained from it since 2 > 11/6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In Section 4, we shall provide the sharpness examples for Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In particular, we shall show  that the thresholds in the statements (i), (ii), (iii) of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 are sharp for any finite field with-  out any further assumptions on the size of the ground field Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In [21], some sharpness examples for  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 (i), (ii) were given but they work with some specific restriction to the size of Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In the proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6, to efficiently estimate a lower bound of W(r), r ̸= 0, we will work  on the product set E × E in 2d-dimensions instead of the set E ⊂ Fd  q, and reduce our problem to  4  the estimate of the explicit Fourier transform on quadratic homogeneous varieties in 2d-dimensional  vector spaces over Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' This method enables us to obtain improved constants on the size conditions  of sets (see, for example, Section 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The rest of this paper will be organized to prove Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Equivalent forms of non-degenerate quadratic forms  Let Q(x) ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd] be a non-degenerate quadratic form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we can write Q(x) = x⊤A x for  some d × d matrix A with det(A) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Using a change of variables, by letting x = Cy for some non-singular  d × d matrix C, it follows that  Q(x) = Q(Cy) = (Cy)⊤A (Cy) = y⊤(C⊤A C) y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Letting B = C⊤A C, we obtain a non-degenerate quadratic form Q′(y) := Q(Cy) = y⊤B y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In summary, after  a non-singular change of variables, the non-degenerate quadratic form Q(x) can be transformed to another  non-degenerate quadratic form Q′(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In this case, we say that Q(x) is equivalent to Q′(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Furthermore, it  is not hard to observe that  ∆Q(E) = ∆Q′(E′),  where E ⊂ Fd  q and E′ := {C−1x : x ∈ E}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In addition, note that |E| = |E′|, and the size assumption of  any sets E is only considered as the main hypothesis for the distance type problems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, without loss of  generality, in the proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 we may choose any non-degenerate quadratic form Q′(x), which is  equivalent to Q(x), as a distance set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now we introduce a concrete quadratic form Q′(x) equivalent to any non-degenerate quadratic form Q(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Let η denote the quadratic character of F∗  q, that is, η(t) = 1 if t is a non-zero square number of Fq, and  η(t) = −1 if t is a non-square number of Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 ([1], Theorem 1 and [17], P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='79).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let A be a d×d a symmetric matrix over Fq with det(A) ̸= 0 and  it is associated with a non-degenerate quadratic form Q(x) ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then the following statements  are true:  (i) If d is even, then the Q(x) is equivalent to  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1)  Q′(x) :=  d−1  �  i=1  (−1)i+1x2  i − εx2  d = x2  1 − x2  2 + · · · + x2  d−1 − εx2  d,  where the ε is taken as any element in F∗  q such that η((−1)  d  2 ε) = η(det(A)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d is odd, then the Q(x) is equivalent to  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2)  Q′(x) :=  d−1  �  i=1  (−1)i+1x2  i + εx2  d = x2  1 − x2  2 + · · · + x2  d−2 − x2  d−1 + εx2  d,  where the ε is taken as any element in F∗  q such that η((−1)  d−1  2 ε) = η(det(A)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In the above lemma, note that if η(ε) = 1, we can simply choose ε = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' On the other hand, if η(−ε) = 1,  then we can take −ε = 1, namely, ε = −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Example 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' When Q(x) = ||x||, it is clear that det(A) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' If d ≡ 2 (mod 4), then, by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (i),  η(−ε) = 1 and so Q(x) = ||x|| can be transformed to the following form:  x2  1 − x2  2 + · · · + x2  d−1 + x2  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  If d ≡ 0 (mod 4), then, by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (i), η(ε) = 1 and so Q(x) = ||x|| can be transformed to the form  below:  x2  1 − x2  2 + · · · + x2  d−1 − x2  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  On the other hand, when d is odd, we can apply Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (ii) to conclude that Q(x) = ||x|| can be  transformed to the quadratic form x2  1 − x2  2 + · · · + x2  d−2 − x2  d−1 − x2  d for d ≡ 3 (mod 4), and to the quadratic  form x2  1 − x2  2 + · · · + x2  d−2 − x2  d−1 + x2  d for d ≡ 1 (mod 4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  For instance, we can consider the following simple, concrete example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  5  Example 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let Q(x) = ||x|| ∈ F3[x1, x2, x3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, by the above example, we know that Q(x) =  x2  1 + x2  2 + x2  3 is equivalent to x2  1 − x2  2 − x2  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Now let us prove this fact by a direct non-singular linear  substitution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' To do this, we note that Q(x) = x⊤I3 x, where I3 denotes the 3 × 3 identity matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We use a  change of variables, by letting x = Cy, where C is the 3×3 non-singular symmetric matrix defined as below:  C =  \uf8eb  \uf8ed  1  0  0  0  1  1  0  1  −1  \uf8f6  \uf8f8 = C⊤.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  It follows that  Q(x) = Q(Cy) = y⊤(C⊤I3C)y = y⊤(C⊤C)y = y⊤  \uf8eb  \uf8ed  1  0  0  0  2  0  0  0  2  \uf8f6  \uf8f8 y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since 2 ≡ −1 (mod 3), we conclude that Q(x) = ||x|| is equivalent to x2  1 − x2  2 − x2  3, as required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  As mentioned in the beginning of this section, we may assume that any non-degenerate quadratic form  Q(x) ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd] can be identified with Q′(x) defined as in Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (i), (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, from now on, we  fix the definition of the non-degenerate quadratic form Q(x), which we will use as the standard distance for  the non-degenerate quadratic form Q(x) ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' (Standard distance functions and its dual functions) Let Q(x) ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd] be a non-  degenerate quadratic form and A be its associated matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we define the standard distance function  || · ||Q and its dual function || · ||Q∗ on Fd  q as follows:  (i) If d is even, then  ||x||Q :=  d−1  �  i=1  (−1)i+1x2  i − εx2  d = x2  1 − x2  2 + · · · + x2  d−1 − εx2  d,  ||m||Q∗ :=  d−1  �  i=1  (−1)i+1m2  i − ε−1m2  d = m2  1 − m2  2 + · · · + m2  d−1 − ε−1m2  d,  where the ε can be taken as any element in F∗  q such that η((−1)  d  2 ε) = η(det(A)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d is odd, then  ||x||Q :=  d−1  �  i=1  (−1)i+1x2  i + εx2  d = x2  1 − x2  2 + · · · + x2  d−2 − x2  d−1 + εx2  d,  ||m||Q∗ :=  d−1  �  i=1  (−1)i+1m2  i + ε−1m2  d = m2  1 − m2  2 + · · · + m2  d−2 − m2  d−1 + ε−1m2  d,  where the ε is taken as any element in F∗  q such that η((−1)  d−1  2 ε) = η(det(A)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We also define the spheres with respect to the distances || · ||Q and || · ||Q∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let t ∈ Fq and Q(x) ∈ Fq[x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd] be a non-degenerate quadratic form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We define  (SQ)t := {x ∈ Fd  q : ||x||Q = t}  and  (SQ∗)t := {m ∈ Fd  q : ||m||Q∗ = t}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The variety (SQ)t can be regarded as a sphere of radius t with the standard distance function || · ||Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The  variety (SQ∗)t can be called the dual sphere of (SQ)t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Basics on the discrete Fourier analysis and related lemmas  The discrete Fourier analysis machinery will function as a main tool in proving Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In this  section, we introduce some basics on it without proofs and review main properties of the Gauss sum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In  addition, we deduce a general counting lemma which will play a key role in the proof of our main theorem,  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  6  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Discrete Fourier analysis and Gauss sums.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We begin by defining the canonical additive character  of Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let q be a power of prime p, say that q = pℓ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The absolute trace function Tr : Fq → Fp is well defined  as Tr(t) = t + tp + tp2 + · · · + tpℓ−1 (for example, see Section 3 of [26]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Definition 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' (Canonical additive character and the quadratic character, [26]) The function χ defined by  χ(c) = e2πiTr(c)/p  for c ∈ Fq  is called the canonical additive character of Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' On the other hand, the multiplicative character η is a function  F∗  q → R, defined by  η(t) =  � 1  if t is a square number of F∗  q,  −1  if t is not a square number of F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Recall that η(−1) = −1 ⇐⇒ q ≡ 3 (mod 4), and η(−1) = 1 ⇐⇒ q ≡ 1 (mod 4) (Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='13, [26]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Both the additive character χ and the multiplicative character ψ enjoy the orthogonality property: For  any m ∈ Fn  q , n ≥ 1,  �  x∈Fn  q  χ(m · x) =  � 0  if m ̸= (0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0)  qn  if m = (0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0),  and  �  t∈F∗q  η(at) = 0  if a ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  where m · x denotes the usual dot product notation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  For a function f : Fn  q → C, the Fourier transform of f is defined as  �f(m) := q−n �  x∈Fn  q  χ(−m · x)f(x)  and the Fourier inversion theorem states that  f(x) =  �  m∈Fn  q  χ(m · x) �f(m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The Plancherel theorem in this context says that  �  m∈Fn  q  | �f(m)|2 = 1  qn  �  x∈Fn  q  |f(x)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In particular, for any set E ⊂ Fn  q , we have  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1)  �  m∈Fn  q  | �E(m)|2 = |E|  qn = �E(0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Here, and throughout this paper, we identify the set E ⊂ Fd  q with the indicator function 1E of the set E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In  particular, when E = (0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0), we write δ0(x) for the indicator function 1E(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We now introduce Gauss sums.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Definition 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let χ, η denote the canonical additive character and the quadratic character of F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The  standard Gauss sum determined by χ and η is defined by  G = G(η, χ) :=  �  t∈F∗q  η(t)χ(t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The following estimate is well-known (see [26]):  |G| = √q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  The following theorem is very useful in finding an explicit value of the Fourier transform on the homoge-  neous variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let G denote the standard Gauss sum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we have  G2 = G(η, χ)2 = η(−1)q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  7  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' It is obvious that η = η and χ(t) = χ(−t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Therefore, it is seen by a change of variables that  G(η, χ) = η(−1)G(η, χ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Hence, G(η, χ)2 = η(−1)|G(η, χ)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since |G(η, χ)| = √q, we are done.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  □  It is not hard to note that for any a ∈ F∗  q,  �  t∈Fq  χ(at2) = η(a)G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Completing the square and using a simple change of variables, the above formula can be generalized to the  formula below: For any a ∈ F∗  q and any b ∈ Fq, we have  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2)  �  t∈Fq  χ(at2 + bt) = η(a)χ  � b2  −4a  �  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  By a change of variables and properties of the quadratic character η, it is not difficult to note that for  b ̸= 0, we have  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3)  �  s∈F∗q  η(s)χ(bs−1) =  �  s∈F∗q  η(bs−1)χ(s) =  �  s∈F∗q  η(bs)χ(s) = η(b)G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' General counting lemma.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In order to prove Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1, the first listed author and Rudnev [20]  evaluated the values of the counting function v(t) in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2) by relating it to the Fourier transform on St :=  {x ∈ Fd  q : ||x|| = t}, the sphere of radius t ∈ F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In this subsection, we formulate their work in the general  setting, which will provide an initial step in estimating W(r) in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now let us work on Fn  q for an integer n ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 (General counting lemma).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let P(x) be a polynomial function on Fn  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Consider an algebraic  variety V := {x ∈ Fn  q : P(x) = 0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, for every set E ⊂ Fn  q , we have  �  x,y∈E:  P (x−y)=0  1 = q2n �  m∈Fn  q  �V (m) |�E(m)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The proof proceeds by modifying the method of the first listed author and Rudnev [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  It follows that  w(0) :=  �  x,y∈E:  P (x−y)=0  1 =  �  x,y∈Fn  q  V (x − y)E(x)E(y).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Applying the Fourier inversion theorem to the indicator function V (x − y), we get  w(0) =  �  x,y∈Fn  q  �  m∈Fn  q  �V (m)χ(m · (x − y))E(x)E(y).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Finally, applying the definition of the Fourier transform �E(m), the statement follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  □  The following is a direct consequence of the general counting lemma.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Corollary 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let Q(x) = ||x||Q for x ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, for every set E ⊂ Fd  q, we have  w(0) :=  �  x,y∈E:  Q(x−y)=0  1 = q2d �  m∈Fdq  �  (SQ)0(m) | �E(m)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' By Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5, recall that  (SQ)0 = {x ∈ Fd  q : Q(x) = 0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then the statement of the corollary immediately follows, because it is a special case of Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 when  n = d, V = (SQ)0, E = E, and P = Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  □  8  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Sharpness of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6  In this section, we provide sharpness examples for the threshold results on Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (i), (ii), (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In  order to construct such sets, it is enough to use the standard quadratic forms in Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 or Definition  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' This is because any non-degenerate quadratic forms that are equivalent yield the same result on the  distance type problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The proof of sharpness of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let the dimension d be even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' When d ≥ 4, we define  a set E1 ⊂ Fd−2  q  as  E1 :=  �  (t1, t1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , ti, ti, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , t(d−2)/2, t(d−2)/2) ∈ Fd−2  q  : ti ∈ Fq, 1 ≤ i ≤ (d − 2)/2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now if d ≥ 4 is even, then define E = E1 × Fq × {0} = {(x′, xd−1, 0) ∈ Fd  q : x′ ∈ E1, xd−1 ∈ Fq}, and if d = 2,  then define E = Fq × {0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since d is even, the standard distance function is given by the form  Q(x) = ||x||Q = x2  1 − x2  2 + · · · + x2  d−1 − εx2  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now notice that |E| = |E1||Fq| = qd/2 and ∆Q(E) = {(a − b)2 : a, b ∈ Fq} = (Fq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since the ratio of  non-zero square numbers is also a square number in Fq, it follows that ∆Q(E)  ∆Q(E) = (Fq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since (Fq)2 ⊊ Fq,  there is r ∈ F∗  q and a set E ⊂ Fd  q with |E| = qd/2 such that r /∈ ∆Q(E)  ∆Q(E), namely, W(r) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In short, the set E provides the desired sharpness example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Notice that, in our construction of the set E,  we did not impose any specific assumptions on the underlying finite field Fq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The proof of sharpness of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since d ≥ 3 is odd, we adopt the following standard  distance function in Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4:  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1)  Q(x) = ||x||Q = x2  1 − x2  2 + · · · + x2  d−2 − x2  d−1 + εx2  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We define a set H ⊂ Fd−1  q  as  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2)  H :=  �  (t1, t1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , ti, ti, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , t(d−1)/2, t(d−1)/2) ∈ Fd−1  q  : ti ∈ Fq, 1 ≤ i ≤ (d − 1)/2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  It is clear that |H| = q(d−1)/2 and the Cartesian product of two sets H and A ⊂ Fq is defined by H × A :=  {(x′, xd) ∈ Fd  q : x′ ∈ H, xd ∈ A}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Letting E = H × A, we see that ∆Q(E) = {ε(a − b)2 : a, b ∈ A} and so  ∆Q(E)  ∆Q(E) =  �  (a−b)2  (a′−b′)2 ∈ Fq : a, b, a′, b′ ∈ A, a′ ̸= b′�  ⊂ (Fq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Let q = pℓ for an integer ℓ ≥ 1 and an odd prime p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then one can consider the finite field Fq as an  ℓ-dimensional vector space over Fp with a basis  �  1, θ, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , θℓ−1�  , where θ is an algebraic element of degree  ℓ over Fp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For every 0 < δ < 1/2, we can choose an arithmetic progression Bδ ⊂ Fp with |Bδ| ∼ p1/2−δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Let us define the set Aδ :=  �  b0 + b1θ + · · · + bℓ−1θℓ−1 : b0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , bℓ−1 ∈ Bδ  �  ⊂ Fq and it is easy to verify that  |Aδ| = |Bδ|ℓ ∼ pℓ/2−δℓ = q1/2−δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' If we consider the difference set of Aδ which is defined as  Aδ − Aδ :=  �  (b0 − b′  0) + (b1 − b′  1)θ + · · · + (bℓ−1 − b′  ℓ−1)θℓ−1 : b0, b′  0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , bℓ−1, b′  ℓ−1 ∈ Bδ  �  ,  then |Aδ − Aδ| = |Bδ − Bδ|ℓ ∼ |Bδ|ℓ ∼ pℓ/2−δℓ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Here we have used the fact that |Bδ − Bδ| ∼ |Bδ| since Bδ  is an arithmetic progression.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Therefore, we have shown that |Aδ − Aδ| ∼ |Aδ|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Set Eδ = H×Aδ ⊂ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then |Eδ| = |H||Aδ| ∼ q  d  2 −δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Observe that ∆Q(Eδ) =  �  ε(a − a′)2 ∈ Fq : a, a′ ∈ Aδ  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since |Aδ −Aδ| ∼ |Aδ|, we see that |∆Q(Eδ)| ∼ |Aδ|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since  ��� ∆Q(Eδ)  ∆Q(Eδ)  ��� ≤ |∆Q(Eδ)|2 ∼ q1−2δ and |(Fq)2| = q+1  2 ,  we conclude that ∆Q(Eδ)  ∆Q(Eδ) ⊊ (Fq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, for every 0 < δ < 1/2, there exists Eδ ⊂ Fd  q with |Eδ| ∼ q  d  2 −δ such  that W(r) = 0 for some non-zero r ∈ (Fq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since δ can be taken as an arbitrary small positive number, the  threshold d/2 cannot be smaller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The proof of sharpness of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that d is odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, we can also use the  standard distance function in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let H ⊂ Fd−1  q  be the set defined as in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Set E := H × Fq ⊂ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then it is not hard to see that |E| = q  d+1  2  and ∆Q(E) = {ε(a − a′)2 : a, a′ ∈ Fq}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Also notice that  ∆Q(E)  ∆Q(E) =  �(a − a′)2  (b − b′)2 : a, a′, b, b′ ∈ Fq, b ̸= b′  �  = (Fq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  9  Clearly, there is r ∈ F∗  q such that r /∈ ∆Q(E)  ∆Q(E), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=', W(r) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, the set E guarantees the sharpness of  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of the main theorem (Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6)  In this section we start proving Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We may assume that Q(x) = ||x||Q and Q∗(m) = ||m||Q∗  for x, m ∈ Fd  q, where ||x||Q and ||m||Q∗ are defined as in Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let E ⊂ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For each r ∈ F∗  q, we  begin with estimating W(r) defined as in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' First observe that W(r) can be written as  W(r) =  �  x,y,z,w∈E:  Q(x−y)=rQ(z−w)  1 −  �  x,y,z,w∈E:  Q(x−y)=0=Q(z−w)  1 =: M(r) − w2(0),  where w(0) is defined by  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1)  w(0) =  �  α,β∈E:  Q(α−β)=0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  To estimate M(r), the first sum above, we write it as  M(r) =  �  (x,z),(y,w)∈E×E:  Q(x−y)−rQ(z−w)=0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We now relate M(r) to an estimate on a homogeneous variety of degree two in F2d  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' To this end, we need to  introduce the following definition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Definition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let r ∈ F∗  q, Q(x) = ||x||Q, and Q∗(m) = ||m||Q∗ for x, m ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, for x, x′, m, m′ ∈ Fd  q,  we define  Qr(x, x′) := Q(x) − rQ(x′)  and  Q∗  r(m, m′) := Q∗(m) − r−1Q∗(m′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In addition, we define algebraic varieties VQr and VQ∗r lying in F2d  q  as follows:  VQr := {X ∈ F2d  q : Qr(X) = 0}  and  VQ∗r := {M ∈ F2d  q : Q∗  r(M) = 0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Letting X = (x, z), Y = (y, w) ∈ E × E and using the notation in the above definition, we have  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2)  M(r) =  �  X,Y ∈E×E:  Qr(X−Y )=0  1 = q4d �  M∈F2d  q  �  VQr(M)| �  E × E(M)|2,  where the last equality follows from the general counting lemma (see Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We will invoke the  following explicit formula for �  VQr(M), whose proof will be given in the following section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For a moment, we  accept the proposition below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For x = (x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xd), m = (m1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , md) ∈ Fd  q, let Q(x) = ||x||Q and Q∗(m) = ||m||Q∗,  where ||x||Q and ||m||Q∗ are defined as in Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, for each r ∈ F∗  q and M ∈ F2d  q , the Fourier  transform �  VQr(M) of the indicator function of the variety VQr in F2d  q  is as follows:  (i) Let d be even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we have  �  VQr(M) = δ0(M)  q  + VQ∗  r(M)  qd  −  1  qd+1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) Let d be odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we have  �  VQr(M) = δ0(M)  q  + η(r)VQ∗r (M)  qd  − η(r)  qd+1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  After replacing �  VQr(M) in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2) by its explicit value given in Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2, we can easily get  M(r) = |E|4  q  + q3d  �  M∈VQ∗r  | �  E × E(M)|2 − qd−1|E|2  for d ≥ 2 even,  10  and  M(r) = |E|4  q  + q3dη(r)  �  M∈VQ∗r  | �  E × E(M)|2 − qd−1η(r)|E|2  for d ≥ 3 odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We also need the following proposition to estimate the quantity w(0) in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let E ⊂ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' For t ∈ Fq, we define w(t) as the number of pairs (x, y) ∈ E × E such that  ||x − y||Q = t, namely,  w(t) :=  �  x,y∈E:  ||x−y||Q=t  1,  where || · ||Q is the standard distance function in Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then the following statements hold true:  (i) If d is even and η (ε) = 1, then we have  0 ≤ w(0) ≤ |E|2  q  + q  3d  2  �  m∈(SQ∗)0  | �E(m)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d is even and η (ε) = −1, then we have  0 ≤ w(0) ≤ |E|2  q  + q  d−2  2 |E|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (iii) If d is odd, then we have  0 ≤ w(0) ≤ |E|2  q  + q  d−1  2 |E|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We postpone the proof of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 to the following section and let us accept it for a moment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since W(r) = M(r) − w2(0), invoking (i),(ii),(iii) of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 together with the estimates of M(r),  lower bounds of W(r) are obtained as follows:  (Case A) If d ≥ 2 is even and η(ε) = 1, then  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3)  W(r) ≥ |E|4  q  + q3d  �  M∈VQ∗r  | �  E × E(M)|2 − qd−1|E|2 −  \uf8eb  \uf8ed|E|2  q  + q  3d  2  �  m∈(SQ∗)0  | �E(m)|2  \uf8f6  \uf8f8  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (Case B) If d ≥ 2 is even and η(ε) = −1, then we have  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4)  W(r) ≥ |E|4  q  + q3d  �  M∈VQ∗r  | �  E × E(M)|2 − qd−1|E|2 −  �|E|2  q  + q  d−2  2 |E|  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (Case C) If d ≥ 3 is odd, then we have  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5)  W(r) ≥ |E|4  q  + q3dη(r)  �  M∈VQ∗r  | �  E × E(M)|2 − qd−1η(r)|E|2 −  �|E|2  q  + q  d−1  2 |E|  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  In the following subsections, we will complete the proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (i), (ii), (iii), by assuming that  Propositions 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 and 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 hold true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let d ≥ 2 be even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that E ⊂ Fd  q with |E| ≥ 4qd/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' It is clear that  η(ε) is either 1 or −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  First, we find a lower bound of W(r) under the assumption of (Case A).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' To do this, we expand the last  term in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3) and observe that  q3d  �  M∈VQ∗r  | �  E × E(M)|2 −  \uf8eb  \uf8edq  3d  2  �  m∈(SQ∗)0  | �E(m)|2  \uf8f6  \uf8f8  2  ≥ 0  and  �  m∈(SQ∗)0  | �E(m)|2 ≤  �  m∈Fdq  | �E(m)|2 = |E|  qd .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  11  Combining these observations and the inequality (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3), we get  W(r) ≥ |E|4  q  − qd−1|E|2 − |E|4  q2  − 2q  d−2  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since 1 =  5  48 + 3  48 + 16  48 + 24  48, we can write |E|4  q  =  5  48  |E|4  q  + 3  48  |E|4  q  + 16  48  |E|4  q  + 24  48  |E|4  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, the lower bound  of W(r) can be written as  W(r) ≥ 5  48  |E|4  q  +  � 3  48  |E|4  q  − qd−1|E|2  �  +  �16  48  |E|4  q  − |E|4  q2  �  +  �24  48  |E|4  q  − 2q  d−2  2 |E|3  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since q ≥ 3 and |E| ≥ 4qd/2, each value in parentheses above is non-negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, we obtain the desired  result:  W(r) ≥ 5  48  |E|4  q  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Next, let us find a lower bound of W(r) under the assumption of (Case B).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We also expand the last term  in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4) and then observe that the sum in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4) can be ignored since it is positive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, we get  W(r) ≥ |E|4  q  − qd−1|E|2 − |E|4  q2  − qd−2|E|2 − 2q  d−4  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since 1 = 20  48 + 3  48 + 16  48 + 1  48 + 8  48, we can write  W(r) ≥ 20  48  |E|4  q  +  � 3  48  |E|4  q  − qd−1|E|2  �  +  �16  48  |E|4  q  − |E|4  q2  �  +  � 1  48  |E|4  q  − qd−2|E|2  �  +  � 8  48  |E|4  q  − 2q  d−4  2 |E|3  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since q ≥ 3 and |E| ≥ 4qd/2, it is not hard to notice that each value in parentheses above is non-negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Hence, in this case we get a better lower bound:  W(r) ≥ 20  48  |E|4  q  ≥ 5  48  |E|4  q  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  This completes the proof of the first part of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let d ≥ 3 be odd and E ⊂ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Assume that r ∈ F∗  q is a non-zero square  number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then η(r) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, it follows from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5) of (Case C) that  W(r) ≥ |E|4  q  + q3d  �  M∈VQ∗r  | �  E × E(M)|2 − qd−1|E|2 −  �|E|2  q  + q  d−1  2 |E|  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Expand the above square term and notice that  �  M∈VQ∗r  | �  E × E(M)|2 ≥ | �  E × E(0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0)|2 = |E|4  q4d .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then we see that  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6)  W(r) ≥ |E|4  q  + |E|4  qd  − qd−1|E|2 − |E|4  q2  − qd−1|E|2 − 2q  d−3  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We now prove the statement of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that |E| ≥ 3qd/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since the term |E|4  qd  in the RHS  of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6) is positive, we can ignore it when we find a lower bound of W(r).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' More precisely, we have  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7)  W(r) ≥ |E|4  q  − 2qd−1|E|2 − |E|4  q2  − 2q  d−3  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since 1 =  2  45 + 10  45 + 15  45 + 18  45, we can write |E|4  q  =  2  45  |E|4  q  + 10  45  |E|4  q  + 15  45  |E|4  q  + 18  45  |E|4  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Therefore, (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='7) becomes  W(r) ≥ 2  45  |E|4  q  +  �10  45  |E|4  q  − 2qd−1|E|2  �  +  �15  45  |E|4  q  − |E|4  q2  �  +  �18  45  |E|4  q  − 2q  d−3  2 |E|3  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since q ≥ 3 and |E| ≥ 3qd/2, each value in parentheses above is non-negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, the required estimate  is obtained:  W(r) ≥ 2  45  |E|4  q  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  12  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that d is odd and r ∈ F∗  q is not a square number, namely,  η(r) = −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' By (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='5) of (Case C),  W(r) ≥ |E|4  q  − q3d  �  M∈VQ∗r  | �  E × E(M)|2 + qd−1|E|2 −  �|E|2  q  + q  d−1  2 |E|  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Expand the last square term above and note that  0 ≤  �  M∈VQ∗r  | �  E × E(M)|2 ≤  �  M∈F2d  q  | �  E × E(M)|2 = |E|2  q2d .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  When r ∈ F∗  q is non-square, we therefore get  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='8)  W(r) ≥ |E|4  q  − qd|E|2 + qd−1|E|2 − |E|4  q2  − qd−1|E|2 − 2q  d−3  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  On the other hand, when r ∈ F∗  q is a square number, we already know from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6) that  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='9)  W(r) ≥ |E|4  q  + |E|4  qd  − qd−1|E|2 − |E|4  q2  − qd−1|E|2 − 2q  d−3  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now let us compare the above two lower bounds of W(r).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' It suffices to compare only the second and third  terms of them since the rest of the terms are equal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since q ≥ 3, it is not hard to see that  −qd|E|2 + qd−1|E|2 < |E|4  qd  − qd−1|E|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  This implies that the lower bound of W(r) in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='8) is much smaller than that in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, the inequality  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='8) holds for all r ∈ F∗  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' In other words, for all r ∈ F∗  q,  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='10)  W(r) ≥ |E|4  q  − qd|E|2 − |E|4  q2  − 2q  d−3  2 |E|3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now we are ready to finish the proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Assume that |E| ≥ 11  6 q  d+1  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since 1 =  2  363 + 108  363 +  121  363 + 132  363, we can write  |E|4  q  =  2  363  |E|4  q  + 108  363  |E|4  q  + 121  363  |E|4  q  + 132  363  |E|4  q  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Combining this with the above inequality (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='10), we get  W(r) ≥  2  363  |E|4  q  +  �108  363  |E|4  q  − qd|E|2  �  +  �121  363  |E|4  q  − |E|4  q2  �  +  �132  363  |E|4  q  − 2q  d−3  2 |E|3  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since q ≥ 3 and |E| ≥ 11  6 q(d+1)/2, we see from a direct computation that each value in parentheses above is  non-negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, we obtain that W(r) ≥  2  363  |E|4  q , which proves Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='6 (iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Propositions 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 and 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3  To efficiently prove the propositions, we begin by deducing a preliminary lemma, regarding the Fourier  transform on the diagonal homogeneous variety of degree two in Fn  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Denote x = (x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , xn), m =  (m1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , mn) ∈ Fn  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let a = (a1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , an) ∈ Fn  q such that aj ̸= 0 for all j = 1, 2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Consider an al-  gebraic variety  Ha :=  \uf8f1  \uf8f2  \uf8f3x ∈ Fn  q :  n  �  j=1  ajx2  j = 0  \uf8fc  \uf8fd  \uf8fe .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We call this variety Ha the diagonal homogeneous variety of degree two with a coefficient vector a in Fn  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  We also define the dual variety of Ha, denoted by Ha∗, as  Ha∗ :=  \uf8f1  \uf8f2  \uf8f3m ∈ Fn  q :  n  �  j=1  a−1  j m2  j = 0  \uf8fc  \uf8fd  \uf8fe .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  13  Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let Ha be the diagonal homogeneous variety of degree two with a coefficient vector a in Fn  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then, for m ∈ Fn  q , the Fourier transform on Ha is given as follows:  (i) If n is even, then  �  Ha(m) = q−1δ0(m) + q− n  2 η  \uf8eb  \uf8ed(−1)n/2  n  �  j=1  aj  \uf8f6  \uf8f8 Ha∗(m) − q−(n+2)/2η  \uf8eb  \uf8ed(−1)n/2  n  �  j=1  aj  \uf8f6  \uf8f8 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If n is odd, then  �  Ha(m) =  \uf8f1  \uf8f4  \uf8f2  \uf8f4  \uf8f3  q−1δ0(m)  if m ∈ Ha∗,  q− n+1  2 η  �  (−1)(n+3)/2  n�  j=1  aj  �  η  �  n�  j=1  a−1  j m2  j  �  if m /∈ Ha∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' The proof uses the standard orthogonality argument of characters and Gauss sum estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  It  follows that  �  Ha(m) = q−n �  x∈Ha  χ(m · x)  = q−n �  x∈Fn  q  \uf8eb  \uf8edq−1 �  s∈Fq  χ  �  s(a1x2  1 + · · · + anx2  n)  �  \uf8f6  \uf8f8 χ(m · x)  = q−1δ0(m) + q−n−1 �  x∈Fn  q  �  s̸=0  χ  �  s(a1x2  1 + · · · + anx2  n)  �  χ(m · x)  = q−1δ0(m) + q−n−1 �  s̸=0  n  �  j=1  �  xj∈Fq  χ(sajx2  j + mjxj).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Summing over xj ∈ Fq by the formula (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2), we get  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1)  �  Ha(m) = q−1δ0(m) + q−n−1Gnη(a1 · · · an)  �  s̸=0  ηn(s)χ  �  − 1  4s  �m2  1  a1  + · · · + m2  n  an  ��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (i) Suppose that n is even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since ηn(s) = 1, the sum over s ̸= 0 is (qHa∗(m) − 1) by application of the  orthogonality of χ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' By Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3, note that Gn = (η(−1)q)n/2 = η((−1)n/2)qn/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' So we obtain that  �  Ha(m) = q−1δ0(m) + q− n+2  2 η((−1)n/2a1 · · · an) (qHa∗(m) − 1) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Hence, the statement of Theorem (i) is proven.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) Suppose that n is odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then ηn = η, and so, if  m2  1  a1 + · · · + m2  n  an  = 0, namely m ∈ Ha∗, then  �  Ha(m) = q−1δ0(m) by the orthogonality of η.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' On the other hand, when m /∈ Ha∗, note by (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3) that  the sum over s ̸= 0 in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1) is equal to η  �  − 1  4  �  m2  1  a1 + · · · + m2  n  an  ��  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Also note that η(−4−1) = η(−1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then we get  �  Ha(m) = q−n−1Gn+1η(−1)η(a1 · · · an)η  �m2  1  a1  + · · · + m2  n  an  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since G2 = η(−1)q by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3, we see that  Gn+1η(−1) = (η(−1)q)(n+1)/2η(−1) = η  �  (−1)(n+3)/2�  q(n+1)/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Inserting this into the above equation, we obtain the required value of �  Ha(m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  □  Now we are ready to prove Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2, which will be a special case of Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  14  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let x, x′ ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then we see that  VQr = {(x, x′) ∈ F2d  q : ||x||Q − r||x′||Q = 0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (i) Suppose that d is even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Then using Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 (i), the coefficient vector of ||x||Q is a′ :=  (1, −1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=', 1, −ε) ∈ Fd  q and that of −r||x′||Q is a′′ := (−r, r, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , −r, rε) ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, VQr is the  diagonal homogeneous variety of degree two with a coefficient vector a = (a′, a′′) in F2d  q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Thus, with  n = 2d even, we can apply the part (i) of Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1, where m = M, Ha = VQr, Ha∗ = VQ∗r, and  η  \uf8eb  \uf8ed  n  �  j=1  aj  \uf8f6  \uf8f8 = η  �  (−1)drdε2�  = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Consequently we obtain that  �  VQr(M) = q−1δ0(M) + q−dη((−1)d)η  �  (−1)drdε2�  VQ∗r(M) − q−(d+1)η((−1)d)η  �  (−1)drdε2�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Since d is even, each value of the above quadratic characters η is 1 and we complete the proof of  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) Suppose that d is odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  By Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4 (ii), we see that a = (a′, a′′) ∈ F2d  q  such that a′ =  (1, −1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=', 1, −1, ε) ∈ Fd  q, and a′′ = (−r, r, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , −r, r, −rε) ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Hence, the proof is the same as the  case of (i) except that for odd d,  η  \uf8eb  \uf8ed  n  �  j=1  aj  \uf8f6  \uf8f8 = η  �  (−1)drdε2�  = η(−r).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Thus, the conclusion of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 (ii) follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since w(0) :=  �  x,y∈E:  ||x−y||Q=0  1, it follows from the general counting lemma  (Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='4) that  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2)  w(0) = q2d �  m∈Fdq  �  (SQ)0(m)| �E(m)|2,  where (SQ)0 = {x ∈ Fd  q : ||x||Q = 0}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' We will invoke the following explicit estimate on the Fourier transform  on (SQ)0, which can be proven by Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Corollary 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let m ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (i) If d is even, then  �  (SQ)0(m) = q−1δ0(m) + q−d/2η(ε)(SQ∗)0(m) − q−(d+2)/2η(ε).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) If d is odd, then  �  (SQ)0(m) =  \uf8f1  \uf8f4  \uf8f2  \uf8f4  \uf8f3  q−1δ0(m)  if m ∈ (SQ∗)0,  q− d+1  2 η(ε)η  �  d−1  �  j=1  (−1)j+1m2  j + ε−1m2  d  �  if m /∈ (SQ∗)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Let a = (a1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , ad) ∈ Fd  q be the coefficient vector of ||x||Q, x ∈ Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then it is clear that (SQ)0 is the  diagonal homogeneous variety of degree two with a coefficient vector a in Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (i) Assume that d is even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then, by definition of ||x||Q, we see that a = (1, −1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 1, −ε) in Fd  q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Since  d�  j=1  aj = (−1)d/2ε, the first part of the corollary follows by applying Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  (ii) Assume that d is odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then a = (1, −1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=', 1, −1, ε) in Fd  q and so  d  �  j=1  aj = (−1)(d−1)/2ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Now applying Lemma 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (ii), we obtain the statement of the second part of the corollary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  15  □  We are now ready to complete the proof of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' By the definition of w(0), it is clear that w(0)  is a non-negative integer, namely, w(0) ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' So it remains to find the required upper bounds for w(0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3-(i), (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that d is even.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Then inserting the value of �  (SQ)0(m) in  Corollary 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 (i) into the formula (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2), we see from a direct computation that  w(0) = |E|2  q  + q3d/2η (ε)  �  m∈(SQ∗)0  | �E(m)|2 − q(d−2)/2|E|η (ε) ,  where we also used the Plancherel theorem (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1) with the simple fact that �E(0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0) = q−d|E|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Notice  that the sign of the second term above is different from that of the third term since η (ε) = ±1 and  �  m∈(SQ∗)0  | �E(m)|2 ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' So, to estimate an upper bound of w(0), we can ignore the negative term which is  exactly one of them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' By this way, we easily obtain the required upper bounds in Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3 (i), (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Proof of Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='3-(iii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Suppose that d is odd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' It is clear from (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2) that  0 ≤ w(0) ≤ q2d �  m∈Fdq  ����  (SQ)0(m)  ��� | �E(m)|2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  On the other hand, Corollary 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2 (ii) implies that  ����  (SQ)0(m)  ��� =  � q−1δ0(m)  if m ∈ (SQ∗)0,  q− d+1  2  if m /∈ (SQ∗)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Thus, combining the above facts, we obtain the desired estimate as follows:  w(0) ≤ q2d �  m∈Fdq  q−1δ0(m)| �E(m)|2 + q2d �  m∈Fdq  q− d+1  2 | �E(m)|2  = q2d−1| �E(0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' , 0)|2 + q2dq− d+1  2  �  m∈Fdq  | �E(m)|2  = |E|2  q  + q  d−1  2 |E|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
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+page_content=' Tr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
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+page_content=' Koh, and Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
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+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' 221  (2017), 95-105.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  [32] I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
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+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Volume 2006, Article  ID 59482, Pages 1-5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  [33] I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Shparlinski, On the additive energy of the distance set in finite fields, Finite Fields Appl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' 42 (2016), 187–199.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  [34] J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Solymosi and V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Vu, Near optimal bounds for the number of distinct distances in high dimensions, Combinatorica, 28,  no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='1 (2008), 113-125.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  [35] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Vinh, On kaleidoscopic pseudo-randomness of finite Euclidean graphs, Discuss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Graph Theory 32 (2012),  no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='2, 279-287.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  [36] L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Vinh, On the generalized Erd˝os-distance problems over finite fields, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content=' Number Theory, 133 (2013), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='9, 2939-2947.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='  Department of Mathematics, University of Rochester, Rochester, NY 14627 USA  Email address: iosevich@math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='rochester.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='edu  Department of Mathematics, Chungbuk National University, Cheongju, Chungbuk 28644 Korea  Email address: koh131@chungbuk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='ac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='kr  Department of Mathematics, University of Rochester, Rochester, NY 14627 USA  Email address: frakhmon@ur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='rochester.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
+page_content='edu  17' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/NNFLT4oBgHgl3EQfNy8i/content/2301.12021v1.pdf'}
diff --git a/ONFJT4oBgHgl3EQfHix_/content/tmp_files/2301.11452v1.pdf.txt b/ONFJT4oBgHgl3EQfHix_/content/tmp_files/2301.11452v1.pdf.txt
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@@ -0,0 +1,1560 @@
+manuscript submitted to Geophysical Research Letters 
+ 
+ 
+Transient Foreshock Structures Upstream of Mars: Implications of the Small 
+Martian Bow Shock 
+H. Madanian1, N. Omidi2, D. G. Sibeck3, L. Andersson1, R. Ramstad1, S. Xu4, J. R. 
+Gruesbeck3, S. J. Schwartz1, R. A. Frahm5, D. A. Brain1, P. Kajdîc6, F. G. Eparvier1, D. L. 
+Mitchell4, S. M. Curry4 
+1Laboratory for Atmospheric and Space Physics, University of Colorado, Boulder, CO, USA 
+2Solana Scientific Inc., Solana Beach, CA,USA 
+3NASA Goddard Space Flight Center, Greenbelt, MD, USA 
+4Space Sciences Laboratory, University of California, Berkeley, CA, USA 
+5Southwest Research Institute, San Antonio, TX, USA 
+6Instituto de Geofísica, Universidad Nacional Autónoma de México, Mexico City, Mexico 
+ 
+Corresponding author: Hadi Madanian (hmadanian@gmail.com)  
+  
+Key Points: 
+• Foreshock bubbles can form upstream of Mars. 
+• Slow field rotations can cause foreshock bubbles while reflected ions from the quasi-
+perpendicular bow shock contribute to their formation. 
+• Unique ion kinetic scale processes exist around foreshock structures at Mars due to the 
+different interaction size scale. 
+ 
+ 
+ 
+
+manuscript submitted to Geophysical Research Letters 
+ 
+Abstract 
+We characterize the nature of magnetic structures in the foreshock region of Mars associated 
+with discontinuities in the solar wind. The structures form at the upstream edge of moving 
+foreshocks caused by slow rotations in the interplanetary magnetic field (IMF). The solar wind 
+plasma density and the IMF strength noticeably decrease inside the structures' core, and a 
+compressional shock layer is present at their sunward side, making them consistent with 
+foreshock bubbles (FBs). Ion populations responsible for these structures include backstreaming 
+ions that only appear within the moving foreshock, and accelerated reflected ions from the quasi-
+perpendicular bow shock. Both ion populations accumulate near the upstream edge of the 
+moving foreshock which facilitates FB formation. Reflected ions with hybrid trajectories that 
+straddle between the quasi-perpendicular and quasi-parallel bow shocks during slow IMF 
+rotations contribute to formation of foreshock transients. 
+Plain Language Summary 
+Planets in the solar system are continuously impacted by the solar wind, a plasma flow 
+originating at the Sun and propagating through the interplanetary medium at high speeds. The 
+solar wind also carries a magnetic field which at times contains twists or discontinuities. The 
+discontinuities are associated with large scale electric currents that can have planar shapes. A 
+planetary obstacle significantly modulate the solar wind plasma and the interaction of solar wind 
+discontinuities with the modulated plasma upstream of the planet leads to formation of transient 
+structures. Due to their relatively large size, these structures can significantly impact and 
+destabilize plasma boundaries at lower altitudes closer to the surface. The results of this paper 
+improve our understanding of solar wind interactions and formation of transient structures 
+upstream of Mars. 
+1 Introduction 
+Plasma environments and the stability of plasma boundaries around terrestrial and planetary 
+objects can be modified by variations in the upstream solar wind conditions (Zhang et al., 2022; 
+Brain et al., 2017; Yamauchi et al., 2011). Some variations stem in the ion foreshock where 
+backstreaming ions reflected at the bow shock interact with the incident solar wind flow. As 
+such, the foreshock region is subject to a variety of instabilities and transient plasma structures 
+(Collinson et al., 2015; Liu et al., 2020; Schwartz et al., 2018; Sibeck et al., 2021; Fowler et al., 
+2018; Omidi et al., 2017; Lee et al., 2021). 
+The solar wind flow also frequently carries discontinuities (rotations), with two common types of 
+rotational (RDs) and tangential discontinuities (TDs) (eugebauer, 2006). RDs are Alfvénic 
+variations and are more frequent than TDs in the solar wind. TDs are non-propagating pressure 
+balanced boundaries that separate two different plasmas that differ in density, temperature, or 
+IMF conditions (Smith, 1973). Unlike TDs, the normal magnetic field component at RDs allows 
+for backstreaming ions or strahl electrons to cross the RD plane (Paschmann et al., 2013). IMF 
+rotations near a bow shock where solar wind interactions are determined by the angle between 
+the shock normal and the upstream interplanetary magnetic field (IMF), 𝜃!", become particularly 
+important. Rotations shift the foreshock region by changing 𝜃!" across the entire bow shock. 
+Passage of a solar wind flux rope bounded by two discontinuities can create a traveling 
+foreshock (Kajdîc et al., 2017), which is formed when the bundle of field lines between the two 
+solar wind discontinuities connect to the bow shock with quasi-parallel geometry.  
+
+manuscript submitted to Geophysical Research Letters 
+ 
+Foreshock bubbles (FBs) are ion kinetic scale transient structures formed due to the interaction 
+of backstreaming ions reflected at the shock with a discontinuity in the solar wind plasma (Omidi 
+et al., 2010). As the name suggests they are isolated shock-like structures that develop in the 
+foreshock ahead of the the main bow shock layer. FBs can form across both TDs and RDs (Liu et 
+al., 2015; Wang et al., 2021), though details of the interaction and associated physical processes 
+are remained to be fully understood. Change in the pitch angle and increase in gyrovelocity of 
+backstreaming ions as they cross the discontinuity lead to the concentration of these particles and 
+increase in their perpendicular temperature and thermal energy upstream of the discontinuity 
+(Archer et al., 2015; Turner et al., 2013; Wang et al., 2021). In addition, change in the amplitude 
+and direction of the motional electric field can also concentrate backstreaming ions into a high-
+pressure plasma layer. These effects consequently lead to the expansion of a plasma bubble 
+against the cold solar wind flow. Unbalanced current densities associated with suprathermal ions, 
+electrons, and solar wind ions create inductive electric fields that drive a magnetic enhancement 
+and a compressional layer on the sunward side of the FB, and a tenuous core on the other side  
+(An et al., 2020; Liu et al., 2020). In spacecraft time series data, FBs are typically manifested as 
+correlated decreases in the solar wind density and the IMF strength which correspond to the core 
+of the FB, followed by a compressional shock layer, the FB shock  (Turner et al., 2013). A 
+foreshock compressional boundary may also be present before the FB which exhibits increases in 
+plasma density and magnetic field strength  (Rojas-Castillo et al., 2013). The shape of FBs are 
+mostly determined by the orientation of the underlying discontinuity plane, ranging from semi-
+spherical to planar, and their size scales with the size of the foreshock  (Omidi et al., 2020; 
+Turner et al., 2020; Lee et al., 2021). Once formed, the entire FB structure convects with the 
+solar wind.  
+Due to the small size of the Martian bow shock which is comparable to the solar wind ion 
+convective gyroradius, foreshock ions at Mars play a more significant role in upstream kinetic 
+processes. Foreshock events have direct impact on heating and thermalization of the solar wind, 
+as well as acceleration of charged particles. Both of these effects can have consequences for 
+space weather at Mars which lacks a global dipole magnetic field. In this paper, we present 
+observational evidence for FBs upstream of Mars and discuss the role of the ion dynamics in 
+generating these structures in comparison to their terrestrial counterparts. 
+2 Data Sources and Method 
+We analyze three events upstream of the Martian bow shock as observed in the Mars 
+Atmosphere and Volatile EvolutioN (MAVEN) spacecraft data (Jakosky et al., 2015). We 
+determine and interpret these events as FBs, noting that there are other transient structures that 
+share some of their properties (Thomsen et al., 1986; Valek et al., 2017). In our analysis, we use 
+magnetic field vectors with 32 Hz sampling rate (Connerney et al., 2015), along with 32 Hz 
+Langmuir probe and waves sweep voltages (LPW-V2) (Andersson et al., 2015), a measure of 
+probe voltage variations corresponding to changes in the surrounding plasma. Electron data from 
+the solar wind electron analyzer (SWEA, (Mitchell et al., 2016)) and the ion measurements from 
+the solar wind ion analyzer (SWIA, (Halekas et al., 2016)) are used. Densities are calculated by 
+integrating the particles distribution function, ∫ 𝑓(𝑣)𝑑#𝑣 over the velocity space. For ions, 𝑓(𝑣) 
+is based on SWIA's entire field-of-view (FOV) and energy bins. For electrons it is based on a 
+Maxwell-Boltzmann fit on energy spectra (assuming an isotropic distribution) 𝑓(𝐸) =
+$
+√& (𝑘'𝑇)(.*𝐸+.*exp	[−
+(-./!")
+1#2 ], where 𝐸 is the electron energy, 𝑇 is the average temperature, 𝑘' 
+
+manuscript submitted to Geophysical Research Letters 
+ 
+is the Boltzmann constant and 𝑉34 is the spacecraft potential. We calculate the ion moments for 
+suprathermal ions from 3D ion distributions when possible, and rely on the difference between 
+SWIA’s solar wind only and total ion moments at other times. These data products have different 
+time resolutions from one another and from the magnetic field data (Madanian et al., 2020; 
+Halekas et al., 2017). The local orientation of the FB shock (𝐧55!,37841) is determined using the 
+minimum variance analysis (MVA) of the magnetic field across the shock layer. When a plasma 
+sheath layer is present before the FB shock and is resolved in observations, 𝐧55!,37841 can also be 
+obtained from the mixed coplanarity method for more accurate estimates (Schwartz, 1998). 𝜃!" 
+is calculated using normal vectors at the point of IMF intersection with the modeled bow shock 
+surface  (Trotignon et al., 2006). The model is a statistical estimate of the shape and standoff 
+distance of the Martian bow shock based on many spacecraft crossings and may not represent the 
+exact conditions of the bow shock layer at a given time. All vector quantities in the paper are in 
+
+manuscript submitted to Geophysical Research Letters 
+ 
+the Mars Solar Orbital (MSO) coordinates in which the 𝑥-axis is towards the Sun and the 𝑦-axis 
+points opposite to Mars' orbital motion. 
+ 
+Figure 1. Plasma and magnetic field data during Event 1 (FB1) on 6 February 2017 at 
+12:03:24 UT. Panels show (a) the magnetic field strength, (b) magnetic field components in 
+MSO coordinates, (c) electron (blue), solar wind ion (black,) total ion (yellow) densities, and 
+scaled LPW-V2 voltages (cyan), (d) ion temperature in the local magnetic field frame 𝑇9(, 𝑇9$, 
+𝑇∥, and the average temperature <T>, (e) solar wind (SW, dashed) and non-solar wind 
+(suprathermal) ion (solid) velocities, (f) ion and (g) electron energy flux spectrograms, (h) 𝜃!" 
+(black) and 𝜃!/ (red, the angle between BIMF and VSW). Panels (i-k) show the spacecraft 
+position along the trajectory around Mars in 𝑥𝑦, 𝑥𝑧, and cylindrical coordinate planes. The FB 
+core is marked with the grey shaded patch and the FB shock layer and sheath is identified by 
+vertical dashed lines. The red dashed circle on panel (c) in this figure marks the density feature 
+associated with the foreshock compressional boundary. 
+ 
+3 Observations 
+Figure 1 shows plasma and magnetic field measurements during the FB1 event observed on 6 
+February 2017. The core region shaded in grey lasts for 36 s in spacecraft data and exhibits 
+rarefied solar wind plasma and reduced IMF strength. An upstream shock layer is also present 
+ 
+ 
+ 
+0
+5
+10
+15
+|B|
+[nT]
+ 
+ 
+ 
+0
+5
+10
+15
+|B|
+[nT]
+ 
+ 
+ 
+-10
+-5
+0
+5
+BMSO
+[nT]
+  Bx
+  By
+  Bz
+ 
+ 
+ 
+-10
+-5
+0
+5
+BMSO
+[nT]
+  Bx
+  By
+  Bz
+ 
+ 
+ 
+0
+5
+10
+Density
+[cm-3]
+  ni,SW
+ 
+ 
+ 
+0
+5
+10
+Density
+[cm-3]
+  ni,SW
+  ne
+  ni
+  LPW-V2
+ 
+ 
+ 
+0
+500
+1000
+Ti
+[eV]
+  T⊥1
+  T⊥2
+  T||
+  <T>
+ 
+ 
+ 
+0
+500
+1000
+Ti
+[eV]
+  T⊥1
+  T⊥2
+  T||
+  <T>
+ 
+ 
+ 
+-600
+-400
+-200
+0
+200
+Vi
+[km/s]
+ 
+ 
+ 
+-600
+-400
+-200
+0
+200
+Vi
+[km/s]
+ 
+ 
+ 
+102
+103
+104
+Ions
+[eV]
+ 
+ 
+ 
+102
+103
+104
+104
+108
+ 
+ 
+ 
+101
+102
+103
+Electrons
+[eV]
+ 
+ 
+ 
+101
+102
+103
+103
+109
+3417.6
+-5338.8
+-598.1
+1202
+3486.1
+-5395.7
+-467.5
+1203
+3552.6
+-5449.5
+-336.7
+1204
+0
+45
+90
+[deg.]
+  BV
+  Bn
+X [km]
+Y [km]
+Z [km]
+hhmm
+2017 Feb 06 
+a)
+a)
+b)
+b)
+c)
+c)
+d)
+d)
+e)
+e)
+f)f)
+g)
+g)
+h)
+h)
+FB shock
+Core
+FB1
+eV/[eV cm2 s str]
+Vx
+Vy
+Vz
+!!"
+!!#
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+i)
+j)
+k)
+MAVEN
+
+manuscript submitted to Geophysical Research Letters 
+ 
+showing plasma density compression and heating of ions and electrons. The FB1 core also 
+contains several substructures (i.e., magnetic peaks). Scaled LPW-V2 data shown in cyan in 
+Figure 1c reveal that some substructures are accompanied by density enhancements and are 
+compressional in nature. Such substructures can be reminiscent of transformation or merging of 
+two or more transient foreshock structures (Vu et al., 2022; Omidi et al., 2020). Inside the core, 
+the solar wind signal initially weakens and then almost disappears. There are some overlaps 
+between solar wind ions and suprathermal ions in SWIA's FOV, and the velocities inside the 
+FB1 core represent the bulk ion flow velocity. The parallel ion temperature (green line in panel 
+(d)) starts increasing before the core onset and reaches ~1000 eV inside the core. The 
+perpendicular temperature increases to the same level inside the core. The electron energy 
+spectrogram in Figure 1.g indicates that some electrons are accelerated to ~100 eV inside the 
+core and near the FB shock layer, which could be due to Fermi acceleration of electrons between 
+the FB and the main shock layer  (Liu et al., 2017). A comprehensive analysis of the acceleration 
+efficiency and occurrence frequency of this processes upstream of Mars is left for a future study.  
+Several overlapping field rotations and ultra-low frequency waves downstream of FB1 
+complicate the selection of a unique magnetic field vector, though all three components of the 
+magnetic field switch sign during this event. FB1 features significantly modulate the underlying 
+discontinuity and its normal vector (𝐧5𝑫) cannot be determined through conventional methods 
+(Neugebauer, 2006). However, the solar wind conditions remain rather unchanged before and 
+after FB1 and the underlying IMF discontinuity is likely a RD. Using the magnetic field and ion 
+velocity vectors within the FB1 sheath just prior to the steep drop in |B|, together with the 
+upstream flow velocity and IMF vectors averaged between 12:03:58 and 12:04:05 UT, we obtain 
+the shock normal vector 𝐧55!,37841=(0.7 ,  -0.4,  0.5) which is within 5° of the MVA estimate. 
+From the conservation of mass flux (Equation 10.29 in Schwartz (1998)), we obtain the FB1 
+shock speed in the spacecraft frame at around 152.8 kms-1 (674.2 kms-1 in the solar wind frame), 
+which is much higher than the upstream fast magnetosonic speed of 47 kms-1 and supports the 
+growth of a compressional magnetosonic shock. Wave activities immediately after the FB1 
+shock with circularly polarized waves at ~2 Hz in the spacecraft frame are observed which could 
+be precursor Whistlers emitted by the FB shock. FBs that expand fast enough into the incident 
+solar wind possess a well-developed shock layer which can have its own foreshock region and 
+emit Whistler precursor waves (Liu et al., 2016). 
+FBs are dynamic structures and the level of wave activity within the core or around the FB shock 
+can vary in different phases of formation. FB2 in Figure 2 is formed at the edge of a moving 
+foreshock bounded by two IMF discontinuities. The magnetic field lines between the two 
+rotations connect to the quasi-parallel bow shock and the event can be viewed as a travelling 
+foreshock  (Kajdîc et al., 2017). Nevertheless, the first rotation in IMF at 07:45:43 UT reduces 
+the local 𝜃!" from ~64° in the downstream solar wind to ~38°. The flux of suprathermal ions 
+increases inside this transient foreshock.  
+The FB2 core and shock are formed near the end of the second discontinuity that begins at 
+07:47:00 UT. The solar wind density is unusually high during this event, 𝒏𝑺𝑾~14.9 cm-3, but the 
+intensity of the solar wind beam observed at 523 eV significantly reduces inside the core and 
+suprathermal ions make up most of the core plasma density 8.6 cm-3. The 𝒏𝒄𝒐𝒓𝒆/𝒏𝑺𝑾 ratio of 
+0.57 in FB2 is roughly the same as that in FB1 (0.53). The plasma density within FB2’s 
+compression layer reaches 66.6 cm-3. Theoretically, the spacecraft potential becomes negative for 
+
+manuscript submitted to Geophysical Research Letters 
+ 
+plasma densities ~20 cm-3 and as such, electron densities are lower at the shock. Similar to FB1, 
+there are magnetic substructures within the FB2 core. However, LPW-V2 measurements show no 
+sign of commensurate plasma density variations associated with the substructures. It is worth 
+noting that a traveling foreshock in time series data corresponds to a “foreshock cavity” which 
+can harbor magnetic perturbations similar to that observed in FB2's core region (Collinson et al., 
+2020; Sibeck et al., 2002). In addition, one edge of a foreshock cavity can be associated with a 
+FB  (Omidi et al., 2013), as is the case for FB2. 
+ 
+Figure 2. An overview of the FB event on 20 May 2019 formed across a travelling foreshock. 
+The figure format is similar to Figure 1. Two RDs associated with the flux rope are indicated 
+in panel b. The y-axis has limited range to emphasize the small amplitude variations within the 
+flux rope. 
+ 
+Simulations of FBs have indicated that when the downstream IMF is roughly parallel to, or 
+makes small angles with the discontinuity plane, as in TDs, the global FB structure is planar in 
+shape. Figure 3 shows an example of a FB forming across a TD. The IMF strength decreases by 
+0.8 nT from the downstream to the upstream side, while the electron and ion densities each 
+increases by 0.5 cm-3. The total solar wind pressure remains constant at 1.02 eV/cm-3, consistent 
+with the TD being the sparatrix between two pressure balanced solar wind plasmas. The normal 
+vector to a TD plane is perpendicular to both upstream and downstream magnetic fields, and for 
+the TD in FB3, it is along 𝐧5B = (0.4, -0.5, 0.7). The MVA estimate of the local normal to the 
+ 
+ 
+ 
+0
+4
+8
+|B|
+[nT]
+  |B|
+ 
+ 
+ 
+0
+4
+8
+|B|
+[nT]
+  |B|
+ 
+ 
+ 
+-4
+-2
+0
+24
+BMSO
+[nT]
+  Bx
+  By
+  Bz
+ 
+ 
+ 
+-4
+-2
+0
+24
+BMSO
+[nT]
+  Bx
+  By
+  Bz
+ 
+ 
+ 
+0
+40
+80
+Density
+[cm-3]
+  ni
+ 
+ 
+ 
+0
+40
+80
+Density
+[cm-3]
+  ni
+  ne
+  ni,SW
+  LPW-V2
+ 
+ 
+ 
+0
+100
+200
+Ti
+[eV]
+  T⊥1
+  T⊥2
+  T||
+  <T>
+ 
+ 
+ 
+0
+100
+200
+Ti
+[eV]
+  T⊥1
+  T⊥2
+  T||
+  <T>
+ 
+ 
+ 
+-400
+0
+400
+Vi
+[km/s]
+  
+  
+  
+ 
+ 
+ 
+-400
+0
+400
+Vi
+[km/s]
+  
+  
+  
+      
+ 
+ 
+ 
+102
+103
+104
+Ions
+[eV]
+ 
+ 
+ 
+102
+103
+104
+105
+108
+ 
+ 
+ 
+101
+102
+103
+Electrons
+[eV]
+ 
+ 
+ 
+101
+102
+103
+105
+108
+3480.5
+5671.2
+3967.7
+0745
+3413.8
+5672.2
+4059.3
+0746
+3346.0
+5671.4
+4149.6
+0747
+0
+45
+90
+[deg.]
+  BV
+  Bn
+X [km]
+Y [km]
+Z [km]
+hhmm
+2019 May 20 
+a)
+a)
+b)
+b)
+c)
+c)
+d)
+d)
+e)
+e)
+f)f)
+g)
+g)
+h)
+h)
+FB shock
+FB2
+flux rope
+Vx
+Vy
+Vz
+eV/[eV cm2 s str]
+RD
+RD
+!!"
+!!#
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+i)
+j)
+k)
+Core
+
+manuscript submitted to Geophysical Research Letters 
+ 
+FB3 shock is 𝐧55!,37841=(0.5, -0.3, 0.8), which is within 15° of 𝐧5B, suggesting that the upstream 
+shock layer is likely formed along the TD plane, and has a planar shape. The FB3 core region 
+corresponds to a period of simultaneous decreases in plasma density and IMF strength and 
+increased flux of suprathermal ions. The shock layer exhibits rather low or modest magnetic field 
+and density compression rates. 
+ 
+Figure 3. The FB3 event observed on 14 June 2019 forming across a TD. The figure format is 
+similar to Figure  4. 
+ 
+Relatively low levels of magnetic perturbations around FB3 compared to FB1 and FB2, and 
+several full 3D ion measurements inside the core makes this event ideal for a more detailed 
+analysis of the dynamics of various ion populations. In Figure 4 we show ion velocity 
+distributions at four timestamps corresponding to red arrows in Figure 3f. The solar wind beam 
+(SW) in these distributions is the intense flux at Vx ~ -350 kms-1 and is used as a reference to 
+identify the other populations. Backstreaming ions propagate opposite to the solar wind while 
+reflected ions accelerated by the motional electric field have a velocity component perpendicular 
+to it and propagate towards downstream (Madanian et al., 2020). Distributions (a) and (b) 
+indicate that in the first half of the core, as 𝜃!/ and 𝜃!" decrease (Figure 2h), the flux of 
+backstreaming ions (BS) increases which results in increased parallel ion temperature. These are 
+reflected ions from the quasi-parallel bow shock and correspond to ion fluxes below the solar 
+ 
+ 
+ 
+0
+2
+4
+|B|
+[nT]
+  |B|
+ 
+ 
+ 
+0
+2
+4
+|B|
+[nT]
+  |B|
+ 
+ 
+ 
+-3
+0
+3
+BMSO
+[nT]
+  Bx
+  By
+  Bz
+ 
+ 
+ 
+-3
+0
+3
+BMSO
+[nT]
+  Bx
+  By
+  Bz
+ 
+ 
+ 
+0
+4
+8
+Density
+[cm-3]
+  ni,SW
+ 
+ 
+ 
+0
+4
+8
+Density
+[cm-3]
+  ni,SW
+  ne
+  ni
+ 
+ 
+ 
+0
+200
+400
+Ti
+[eV]
+  T⊥1
+  T⊥2
+  T||
+  <T>
+ 
+ 
+ 
+0
+200
+400
+Ti
+[eV]
+  T⊥1
+  T⊥2
+  T||
+  <T>
+ 
+ 
+ 
+-600
+-400
+-200
+0
+200
+Vi
+[km/s]
+  Vx
+  Vy
+  Vz
+ 
+ 
+ 
+-600
+-400
+-200
+0
+200
+Vi
+[km/s]
+  Vx
+  Vy
+  Vz
+ 
+ 
+ 
+102
+103
+104
+Ions
+[eV]
+ 
+ 
+ 
+102
+103
+104
+104
+108
+ 
+ 
+ 
+101
+102
+103
+Electrons
+[eV]
+ 
+ 
+ 
+101
+102
+103
+104
+108
+4964.6
+3730.5
+4590.9
+1910
+4865.9
+3754.0
+4643.3
+1911
+4765.5
+3776.1
+4694.2
+1912
+0
+45
+90
+[deg.]
+  BV
+  Bn
+X [km]
+Y [km]
+Z [km]
+hhmm
+2019 Jun 14 
+a)
+a)
+b)
+b)
+c)
+c)
+d)
+d)
+e)
+e)
+f)f)
+g)
+g)
+h)
+h)
+eV/[eV cm2 s str]
+FB shock
+FB3
+Core
+!!"
+!!#
+B!"#,%&
+B!"#,'(
+TD
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Y [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+-4
+-2
+0
+2
+4
+Z [RM]
+-4
+-2
+0
+2
+4
+X [RM]
+0
+1
+2
+3
+4
+S [RM]
+i)
+j)
+k)
+
+manuscript submitted to Geophysical Research Letters 
+ 
+wind beam energy in Figure 2f. With increasing 𝜃!" and 𝜃!/ in the second half of the core, 
+backstreaming ions disappear from the FOV and the motional electric field drives the reflected 
+ion beam downstream before they reach the spacecraft. 
+ 
+Figure 4. 2D cuts through ion phase space velocity distributions at four timestamps across the 
+event on 14 June 2019 (red arrows in Figure 3). The solar wind beam (SW) backstreaming 
+(BS) and accelerated suprathermal (STH) ion populations are labeled on each panel. The 
+dashed black lines show the projection of the magnetic field direction in the plane of the 
+distributions. 
+ 
+As the IMF changes direction (dashed black lines on Figure 4 panels) the suprathermal ions 
+("STH") continue to enter the instrument from roughly the same direction which indicates that 
+these ions are not sourced locally. These ions propagate anti-sunward and their energies are 
+ 
+ 
+ 
+ 
+ 
+-5
+0
+5
+Vy [ x102 km/s]
+a)
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+ 
+103
+104
+105
+106
+107
+108
+f [s
+3/km
+6]
+b)
+ 
+-5
+0
+5
+Vx [ x102 km/s]
+-5
+0
+5
+Vy [ x102 km/s]
+c)
+ 
+-5
+0
+5
+Vx [ x102 km/s]
+ 
+ 
+ 
+ 
+d)
+a) 19:11:09
+b) 19:11:17
+c) 19:11:25
+d) 19:11:33
+SW
+BS
+STH
+STH
+STH
+BS
+SW
+SW
+SW
+
+manuscript submitted to Geophysical Research Letters 
+ 
+above the solar wind beam energy, indicating that they have likely been reflected at the quasi-
+perpendicular side of the bow shock. 
+4 Discussions 
+Due to the small curvature radius of the Martial bow shock compared to the upstream ion 
+gyroradius, energization of solar wind ions via multiple shock crossing, as in planar shocks, may 
+not be feasible (urgess, 1987; Burgess et al., 2012). However, reflected ion trajectories can 
+overlap between quasi-parallel and quasi-perpendicular regions (Moses et al., 1988). Past hybrid 
+simulations and observational studies at Earth have demonstrated that FBs form when a 
+discontinuity convected by the solar wind encounters backstreaming ions in the foreshock region 
+of the quasi-parallel bow shock  (Omidi et al., 2010; Liu et al., 2016). In Figures 1, 2, 3 
+signatures of ion temperature variations across FBs resembling the observations of FBs at Earth 
+were discussed. To demonstrate the implications of different size scales at Mars and identify the 
+source region of peculiar ion distributions that cause the temperature variations on transient 
+foreshock structures we developed a test particle model to identify the source and trajectory of 
+ion populations in FB3. We track a number of solar wind test particle protons in static and 
+uniform electric and magnetic fields, and update the 3D position and velocity of particles at each 
+step by integrating the Lorentz force on the particles. Each particle undergoes one specular 
+reflection from the nominal bow shock. Wave-particle interactions and other foreshock effects 
+are not included in this simple model. 
+ 
+Figure 5. 3D view of test particle simulation results showing solar wind proton trajectories in 
+static fields across FB3. Mars’s bow shock surface is color coded by 𝜃!" (top colorbars), while 
+the color along each trajectory indicates the simulation time (colorbars on the right). The 
+MAVEN spacecraft position is indicated with a green marker. Panels (a) and (b) correspond to 
+the solar wind conditions at the time of distributions (a) and (c) respectively, in Figure 4. 
+The left panel in Figure 5 shows the ion trajectories under upstream conditions at 19:11:09 UT 
+before the FB3 onset. Backstreaming ions appear near the nose of the bow shock, some of which 
+a)
+b)
+
+4
+BIMF
+-4
+Econ.
+-2
+0
+2
+MSO
+M
+4美头
+0
+MS
+-2
+0
+2
+4
+X
+[RM]
+MSO
+M0
+2Bn
+45
+90
+130
+Time [s]
+87
+43R
+0
+MS(
+-2
+Econ.
+4
+-2
+0
+Y
+R
+MSO
+M-2
+0
+MS
+2
+B
+IMF
+X
+[R
+4
+MSO
+M
+2
+40 Bn
+0
+45
+9
+20
+109
+Time [s]
+73
+Maven
+36
+0manuscript submitted to Geophysical Research Letters 
+ 
+have trajectories that cross the MAVEN position. These ions are consistent with the "BS" ion 
+population in Figures 4a and b. In all three events, the ion foreshock and associated parallel 
+temperature enhancements appear with the onset of the discontinuity and are caused by the slow 
+IMF rotation. This is a distinguishing aspect of Martian FBs from terrestrial cases which are 
+formed when an upstream discontinuity convected by the solar wind encounters backstreaming 
+ions in the foreshock region of Earth's quasi-parallel bow shock (Omidi et al., 2010; Liu et al., 
+2016).  
+Figure 5b shows ion trajectories under the solar wind and IMF conditions in the middle of FB3's 
+core at 19:11:25 UT are shown. Non-solar wind ions that reach MAVEN at this time have been 
+reflected from the quasi-perpendicular regions of the bow shock (Madanian et al., 2020), and 
+after having been accelerated by the motional electric field interact with the upstream 
+discontinuity. These ions form the "STH" population in Figure 4 b, c, and d causing the increase 
+in the perpendicular ion temperature (Figure 3d).  
+5 Conclusions 
+We report for the first time detailed analysis of FB events upstream of Mars formed across a 
+rotational discontinuity (FB1), a travelling foreshock (FB2), and a tangential discontinuity (FB3). 
+Waves associated with exospheric pickup ions were either absent or weak during these events. 
+For each event we discuss signatures in the magnetic field and plasma moments that are similar 
+and consistent with FB signatures at the terrestrial bow shock. The observations in this study 
+confirm the expectation of FBs being associated with the presence of backstreaming ions and 
+solar wind discontinuities. 
+The results of our test particle model demonstrate that based on the size of the Martian bow 
+shock and the gyro-radius of the ions reflected from the quasi-perpendicular bow shock it is 
+possible for them to travel sufficiently far upstream to contribute to FB formation at Mars. Even 
+though the Martian foreshock is small compared to that at Earth, backstreaming ion fluxes 
+emerging during slow IMF rotations, and reflected ions from the quasi-perpendicular bow shock 
+that reach the discontinuity can be sufficient to provide the necessary pressure increase for FB 
+formation.  
+Embedded solar wind discontinuities are a frequent phenomenon at 1 AU (Neugebauer, 2006; 
+Schwartz et al., 2000), and associated foreshock structures have a significant impact on Earth’s 
+magnetosphere and ionosphere (Archer et al., 2015; Sibeck et al., 1999; Wang et al., 2018). At 
+Venus, FBs disturb the pressure balance at ionospheric altitudes and uplift the ionospheric heavy 
+ion species, making them more accessible to the pickup process  (Omidi et al., 2020). Given the 
+general similarities in solar wind conditions upstream of Mars and Earth (Liu et al., 2021), and 
+the increase in the solar wind speed and Mach number which favor generation of transient 
+foreshock structures, it is likely that these structures cause disturbances at Mars, particularly due 
+to the lack of a global dipole magnetic field. The global impact of these kinetic scale processes 
+on Mars can be better quantified with multi-point observations. At the time of events discussed 
+here, the Mars Express (MEx) spacecraft was in orbit around Mars, however; it was not in a 
+
+manuscript submitted to Geophysical Research Letters 
+ 
+good position to provide complimentary information to our analysis. Future multi-point analyses 
+will benefit from all active spacecraft around Mars. 
+ 
+Acknowledgments 
+We acknowledge the MAVEN contract for support. The original funding proposal for this 
+research was not supported by NASA. PK's work was supported by DGAPA/PAPIIT grant 
+IN105620. 
+   
+Open Research 
+All data used in this study are publicly available through the Planetary Data System at 
+https://pds-ppi.igpp.ucla.edu/mission/MAVEN/, under each instrument name, e.g., 
+https://doi.org/10.17189/1414178 for magnetometer and https://doi.org/10.17189/1410658 for 
+LPW data. Further information on each data set is included in references in Section 2. 
+  
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+
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+page_content='manuscript submitted to Geophysical Research Letters  Transient Foreshock Structures Upstream of Mars: Implications of the Small Martian Bow Shock H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Madanian1, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Omidi2, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Sibeck3, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Andersson1, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Ramstad1, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Xu4, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Gruesbeck3, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Schwartz1, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Frahm5, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Brain1, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Kajdîc6, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Eparvier1, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Mitchell4, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Curry4 1Laboratory for Atmospheric and Space Physics, University of Colorado, Boulder, CO, USA 2Solana Scientific Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Solana Beach, CA,USA 3NASA Goddard Space Flight Center, Greenbelt, MD, USA 4Space Sciences Laboratory, University of California, Berkeley, CA, USA 5Southwest Research Institute, San Antonio, TX, USA 6Instituto de Geofísica, Universidad Nacional Autónoma de México, Mexico City, Mexico  Corresponding author: Hadi Madanian (hmadanian@gmail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='com)  Key Points: • Foreshock bubbles can form upstream of Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' • Slow field rotations can cause foreshock bubbles while reflected ions from the quasi- perpendicular bow shock contribute to their formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' • Unique ion kinetic scale processes exist around foreshock structures at Mars due to the different interaction size scale.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  manuscript submitted to Geophysical Research Letters  Abstract We characterize the nature of magnetic structures in the foreshock region of Mars associated with discontinuities in the solar wind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The structures form at the upstream edge of moving foreshocks caused by slow rotations in the interplanetary magnetic field (IMF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" The solar wind plasma density and the IMF strength noticeably decrease inside the structures' core, and a compressional shock layer is present at their sunward side, making them consistent with foreshock bubbles (FBs)." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Ion populations responsible for these structures include backstreaming ions that only appear within the moving foreshock, and accelerated reflected ions from the quasi- perpendicular bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Both ion populations accumulate near the upstream edge of the moving foreshock which facilitates FB formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Reflected ions with hybrid trajectories that straddle between the quasi-perpendicular and quasi-parallel bow shocks during slow IMF rotations contribute to formation of foreshock transients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Plain Language Summary Planets in the solar system are continuously impacted by the solar wind, a plasma flow originating at the Sun and propagating through the interplanetary medium at high speeds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The solar wind also carries a magnetic field which at times contains twists or discontinuities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The discontinuities are associated with large scale electric currents that can have planar shapes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  A planetary obstacle significantly modulate the solar wind plasma and the interaction of solar wind discontinuities with the modulated plasma upstream of the planet leads to formation of transient structures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Due to their relatively large size, these structures can significantly impact and destabilize plasma boundaries at lower altitudes closer to the surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The results of this paper improve our understanding of solar wind interactions and formation of transient structures upstream of Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 1 Introduction Plasma environments and the stability of plasma boundaries around terrestrial and planetary objects can be modified by variations in the upstream solar wind conditions (Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Brain et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Yamauchi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2011).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Some variations stem in the ion foreshock where backstreaming ions reflected at the bow shock interact with the incident solar wind flow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' As such, the foreshock region is subject to a variety of instabilities and transient plasma structures (Collinson et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Schwartz et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2018;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Sibeck et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2021;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Fowler et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2018;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Lee et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The solar wind flow also frequently carries discontinuities (rotations), with two common types of rotational (RDs) and tangential discontinuities (TDs) (eugebauer, 2006).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' RDs are Alfvénic variations and are more frequent than TDs in the solar wind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  TDs are non-propagating pressure balanced boundaries that separate two different plasmas that differ in density, temperature, or IMF conditions (Smith, 1973).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Unlike TDs, the normal magnetic field component at RDs allows for backstreaming ions or strahl electrons to cross the RD plane (Paschmann et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2013).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' IMF rotations near a bow shock where solar wind interactions are determined by the angle between the shock normal and the upstream interplanetary magnetic field (IMF), 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' ", become particularly important.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Rotations shift the foreshock region by changing 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" across the entire bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Passage of a solar wind flux rope bounded by two discontinuities can create a traveling foreshock (Kajdîc et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017), which is formed when the bundle of field lines between the two solar wind discontinuities connect to the bow shock with quasi-parallel geometry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  manuscript submitted to Geophysical Research Letters  Foreshock bubbles (FBs) are ion kinetic scale transient structures formed due to the interaction of backstreaming ions reflected at the shock with a discontinuity in the solar wind plasma (Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2010).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' As the name suggests they are isolated shock-like structures that develop in the foreshock ahead of the the main bow shock layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' FBs can form across both TDs and RDs (Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2021), though details of the interaction and associated physical processes are remained to be fully understood.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Change in the pitch angle and increase in gyrovelocity of backstreaming ions as they cross the discontinuity lead to the concentration of these particles and increase in their perpendicular temperature and thermal energy upstream of the discontinuity (Archer et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Turner et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2013;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In addition, change in the amplitude and direction of the motional electric field can also concentrate backstreaming ions into a high- pressure plasma layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' These effects consequently lead to the expansion of a plasma bubble against the cold solar wind flow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Unbalanced current densities associated with suprathermal ions, electrons, and solar wind ions create inductive electric fields that drive a magnetic enhancement and a compressional layer on the sunward side of the FB, and a tenuous core on the other side (An et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  In spacecraft time series data, FBs are typically manifested as correlated decreases in the solar wind density and the IMF strength which correspond to the core of the FB, followed by a compressional shock layer, the FB shock  (Turner et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2013).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A foreshock compressional boundary may also be present before the FB which exhibits increases in plasma density and magnetic field strength  (Rojas-Castillo et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2013).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The shape of FBs are mostly determined by the orientation of the underlying discontinuity plane, ranging from semi- spherical to planar, and their size scales with the size of the foreshock  (Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Turner et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Lee et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Once formed, the entire FB structure convects with the solar wind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Due to the small size of the Martian bow shock which is comparable to the solar wind ion convective gyroradius, foreshock ions at Mars play a more significant role in upstream kinetic processes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Foreshock events have direct impact on heating and thermalization of the solar wind, as well as acceleration of charged particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Both of these effects can have consequences for space weather at Mars which lacks a global dipole magnetic field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In this paper, we present observational evidence for FBs upstream of Mars and discuss the role of the ion dynamics in generating these structures in comparison to their terrestrial counterparts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  2 Data Sources and Method We analyze three events upstream of the Martian bow shock as observed in the Mars Atmosphere and Volatile EvolutioN (MAVEN) spacecraft data (Jakosky et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' We determine and interpret these events as FBs, noting that there are other transient structures that share some of their properties (Thomsen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 1986;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Valek et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In our analysis, we use magnetic field vectors with 32 Hz sampling rate (Connerney et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015), along with 32 Hz Langmuir probe and waves sweep voltages (LPW-V2) (Andersson et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015), a measure of probe voltage variations corresponding to changes in the surrounding plasma.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Electron data from the solar wind electron analyzer (SWEA, (Mitchell et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2016)) and the ion measurements from the solar wind ion analyzer (SWIA, (Halekas et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2016)) are used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Densities are calculated by integrating the particles distribution function, ∫ 𝑓(𝑣)𝑑#𝑣 over the velocity space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" For ions, 𝑓(𝑣) is based on SWIA's entire field-of-view (FOV) and energy bins." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" For electrons it is based on a Maxwell-Boltzmann fit on energy spectra (assuming an isotropic distribution) 𝑓(𝐸) = $ √& (𝑘'𝑇)(." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='*𝐸+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' *exp [− (-.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='/!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='") 1#2 ], where 𝐸 is the electron energy, 𝑇 is the average temperature, 𝑘\'  manuscript submitted to Geophysical Research Letters  is the Boltzmann constant and 𝑉34 is the spacecraft potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' We calculate the ion moments for suprathermal ions from 3D ion distributions when possible, and rely on the difference between SWIA’s solar wind only and total ion moments at other times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' These data products have different time resolutions from one another and from the magnetic field data (Madanian et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Halekas et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The local orientation of the FB shock (𝐧55!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=',37841) is determined using the minimum variance analysis (MVA) of the magnetic field across the shock layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' When a plasma sheath layer is present before the FB shock and is resolved in observations, 𝐧55!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=',37841 can also be obtained from the mixed coplanarity method for more accurate estimates (Schwartz, 1998).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" is calculated using normal vectors at the point of IMF intersection with the modeled bow shock surface  (Trotignon et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2006).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The model is a statistical estimate of the shape and standoff distance of the Martian bow shock based on many spacecraft crossings and may not represent the exact conditions of the bow shock layer at a given time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" All vector quantities in the paper are in  manuscript submitted to Geophysical Research Letters  the Mars Solar Orbital (MSO) coordinates in which the 𝑥-axis is towards the Sun and the 𝑦-axis points opposite to Mars' orbital motion." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Plasma and magnetic field data during Event 1 (FB1) on 6 February 2017 at 12:03:24 UT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Panels show (a) the magnetic field strength, (b) magnetic field components in MSO coordinates, (c) electron (blue), solar wind ion (black,) total ion (yellow) densities, and scaled LPW-V2 voltages (cyan), (d) ion temperature in the local magnetic field frame 𝑇9(, 𝑇9$, 𝑇∥, and the average temperature <T>, (e) solar wind (SW, dashed) and non-solar wind (suprathermal) ion (solid) velocities, (f) ion and (g) electron energy flux spectrograms, (h) 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" (black) and 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='/ (red, the angle between BIMF and VSW).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Panels (i-k) show the spacecraft position along the trajectory around Mars in 𝑥𝑦, 𝑥𝑧, and cylindrical coordinate planes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The FB core is marked with the grey shaded patch and the FB shock layer and sheath is identified by vertical dashed lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The red dashed circle on panel (c) in this figure marks the density feature associated with the foreshock compressional boundary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  3 Observations Figure 1 shows plasma and magnetic field measurements during the FB1 event observed on 6 February 2017.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The core region shaded in grey lasts for 36 s in spacecraft data and exhibits rarefied solar wind plasma and reduced IMF strength.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' An upstream shock layer is also present  0  5  10  15  |B|  [nT]  0  5  10  15  |B|  [nT]  10  5 0 5 BMSO [nT] Bx By Bz  10  5 0 5 BMSO [nT] Bx By Bz  0  5  10  Density  [cm 3]  ni,SW  0  5  10  Density  [cm 3]  ni,SW  ne  ni  LPW V2  0  500  1000  Ti  [eV]  T⊥1  T⊥2  T||  <T>  0  500  1000  Ti  [eV]  T⊥1  T⊥2  T||  <T>  600  400  200 0 200 Vi [km/s]  600  400  200 0 200 Vi [km/s]  102  103  104  Ions  [eV]  102  103  104  104  108  101  102  103  Electrons  [eV]  101  102  103  103  109  3417.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='6 5338.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='8 598.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1  1202  3486.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1 5395.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='7 467.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5  1203  3552.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='6 5449.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5 336.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='7  1204  0  45  90  [deg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=']  BV  Bn  X [km]  Y [km]  Z [km]  hhmm  2017 Feb 06  a)  a)  b)  b)  c)  c)  d)  d)  e)  e)  f)f)  g)  g)  h)  h)  FB shock  Core  FB1  eV/[eV cm2 s str]  Vx  Vy  Vz  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='MAVEN  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='manuscript submitted to Geophysical Research Letters  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='showing plasma density compression and heating of ions and electrons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The FB1 core also contains several substructures (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', magnetic peaks).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Scaled LPW-V2 data shown in cyan in Figure 1c reveal that some substructures are accompanied by density enhancements and are compressional in nature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Such substructures can be reminiscent of transformation or merging of two or more transient foreshock structures (Vu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Inside the core, the solar wind signal initially weakens and then almost disappears.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" There are some overlaps between solar wind ions and suprathermal ions in SWIA's FOV, and the velocities inside the FB1 core represent the bulk ion flow velocity." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The parallel ion temperature (green line in panel (d)) starts increasing before the core onset and reaches ~1000 eV inside the core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The perpendicular temperature increases to the same level inside the core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The electron energy spectrogram in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='g indicates that some electrons are accelerated to ~100 eV inside the core and near the FB shock layer, which could be due to Fermi acceleration of electrons between the FB and the main shock layer  (Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A comprehensive analysis of the acceleration efficiency and occurrence frequency of this processes upstream of Mars is left for a future study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Several overlapping field rotations and ultra-low frequency waves downstream of FB1 complicate the selection of a unique magnetic field vector, though all three components of the magnetic field switch sign during this event.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' FB1 features significantly modulate the underlying discontinuity and its normal vector (𝐧5𝑫) cannot be determined through conventional methods (Neugebauer, 2006).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' However, the solar wind conditions remain rather unchanged before and after FB1 and the underlying IMF discontinuity is likely a RD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Using the magnetic field and ion velocity vectors within the FB1 sheath just prior to the steep drop in |B|, together with the upstream flow velocity and IMF vectors averaged between 12:03:58 and 12:04:05 UT, we obtain the shock normal vector 𝐧55!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=',37841=(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='7 ,  -0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='4,  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5) which is within 5° of the MVA estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' From the conservation of mass flux (Equation 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='29 in Schwartz (1998)), we obtain the FB1 shock speed in the spacecraft frame at around 152.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='8 kms-1 (674.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='2 kms-1 in the solar wind frame), which is much higher than the upstream fast magnetosonic speed of 47 kms-1 and supports the growth of a compressional magnetosonic shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Wave activities immediately after the FB1 shock with circularly polarized waves at ~2 Hz in the spacecraft frame are observed which could be precursor Whistlers emitted by the FB shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  FBs that expand fast enough into the incident solar wind possess a well-developed shock layer which can have its own foreshock region and emit Whistler precursor waves (Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' FBs are dynamic structures and the level of wave activity within the core or around the FB shock can vary in different phases of formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' FB2 in Figure 2 is formed at the edge of a moving foreshock bounded by two IMF discontinuities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The magnetic field lines between the two rotations connect to the quasi-parallel bow shock and the event can be viewed as a travelling foreshock  (Kajdîc et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Nevertheless, the first rotation in IMF at 07:45:43 UT reduces the local 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" from ~64° in the downstream solar wind to ~38°.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The flux of suprathermal ions increases inside this transient foreshock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The FB2 core and shock are formed near the end of the second discontinuity that begins at 07:47:00 UT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The solar wind density is unusually high during this event, 𝒏𝑺𝑾~14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='9 cm-3, but the intensity of the solar wind beam observed at 523 eV significantly reduces inside the core and suprathermal ions make up most of the core plasma density 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='6 cm-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The 𝒏𝒄𝒐𝒓𝒆/𝒏𝑺𝑾 ratio of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='57 in FB2 is roughly the same as that in FB1 (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='53).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The plasma density within FB2’s compression layer reaches 66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='6 cm-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Theoretically, the spacecraft potential becomes negative for  manuscript submitted to Geophysical Research Letters  plasma densities ~20 cm-3 and as such, electron densities are lower at the shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Similar to FB1, there are magnetic substructures within the FB2 core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' However, LPW-V2 measurements show no sign of commensurate plasma density variations associated with the substructures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" It is worth noting that a traveling foreshock in time series data corresponds to a “foreshock cavity” which can harbor magnetic perturbations similar to that observed in FB2's core region (Collinson et al." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Sibeck et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2002).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In addition, one edge of a foreshock cavity can be associated with a FB  (Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2013), as is the case for FB2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' An overview of the FB event on 20 May 2019 formed across a travelling foreshock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The figure format is similar to Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Two RDs associated with the flux rope are indicated in panel b.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The y-axis has limited range to emphasize the small amplitude variations within the flux rope.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Simulations of FBs have indicated that when the downstream IMF is roughly parallel to, or makes small angles with the discontinuity plane, as in TDs, the global FB structure is planar in shape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Figure 3 shows an example of a FB forming across a TD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The IMF strength decreases by 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='8 nT from the downstream to the upstream side, while the electron and ion densities each increases by 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5 cm-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The total solar wind pressure remains constant at 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='02 eV/cm-3, consistent with the TD being the sparatrix between two pressure balanced solar wind plasmas.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The normal vector to a TD plane is perpendicular to both upstream and downstream magnetic fields, and for the TD in FB3, it is along 𝐧5B = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='4, -0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The MVA estimate of the local normal to the  0  4  8  |B|  [nT]  |B|  0  4  8  |B|  [nT]  |B|  4  2 0 24 BMSO [nT] Bx By Bz  4  2 0 24 BMSO [nT] Bx By Bz  0  40  80  Density  [cm 3]  ni  0  40  80  Density  [cm 3]  ni  ne  ni,SW  LPW V2  0  100  200  Ti  [eV]  T⊥1  T⊥2  T||  <T>  0  100  200  Ti  [eV]  T⊥1  T⊥2  T||  <T>  400 0 400 Vi [km/s]  400 0 400 Vi [km/s]  102  103  104  Ions  [eV]  102  103  104  105  108  101  102  103  Electrons  [eV]  101  102  103  105  108  3480.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5  5671.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='2  3967.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='7  0745  3413.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='8  5672.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='2  4059.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='3  0746  3346.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='0  5671.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='4  4149.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='6  0747  0  45  90  [deg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=']  BV  Bn  X [km]  Y [km]  Z [km]  hhmm  2019 May 20  a)  a)  b)  b)  c)  c)  d)  d)  e)  e)  f)f)  g)  g)  h)  h)  FB shock  FB2  flux rope  Vx  Vy  Vz  eV/[eV cm2 s str]  RD  RD  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='"  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='# 4 2  0  2  4  X [RM] 4 2  0  2  4  Y [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Z [RM] 4 2  0  2  4  X [RM]  0  1  2  3  4  S [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Y [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Z [RM] 4 2  0  2  4  X [RM]  0  1  2  3  4  S [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Y [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Z [RM] 4 2  0  2  4  X [RM]  0  1  2  3  4  S [RM]  i)  j)  k)  Core  manuscript submitted to Geophysical Research Letters  FB3 shock is 𝐧55!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=',37841=(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5, -0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='3, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='8), which is within 15° of 𝐧5B, suggesting that the upstream shock layer is likely formed along the TD plane, and has a planar shape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The FB3 core region corresponds to a period of simultaneous decreases in plasma density and IMF strength and increased flux of suprathermal ions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The shock layer exhibits rather low or modest magnetic field and density compression rates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The FB3 event observed on 14 June 2019 forming across a TD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The figure format is similar to Figure  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Relatively low levels of magnetic perturbations around FB3 compared to FB1 and FB2, and several full 3D ion measurements inside the core makes this event ideal for a more detailed analysis of the dynamics of various ion populations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In Figure 4 we show ion velocity distributions at four timestamps corresponding to red arrows in Figure 3f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The solar wind beam (SW) in these distributions is the intense flux at Vx ~ -350 kms-1 and is used as a reference to identify the other populations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Backstreaming ions propagate opposite to the solar wind while reflected ions accelerated by the motional electric field have a velocity component perpendicular to it and propagate towards downstream (Madanian et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Distributions (a) and (b) indicate that in the first half of the core, as 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='/ and 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" decrease (Figure 2h), the flux of backstreaming ions (BS) increases which results in increased parallel ion temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' These are reflected ions from the quasi-parallel bow shock and correspond to ion fluxes below the solar  0  2  4  |B|  [nT]  |B|  0  2  4  |B|  [nT]  |B|  3 0 3 BMSO [nT] Bx By Bz  3 0 3 BMSO [nT] Bx By Bz  0  4  8  Density  [cm 3]  ni,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='SW  0  4  8  Density  [cm 3]  ni,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='SW  ne  ni  0  200  400  Ti  [eV]  T⊥1  T⊥2  T||  <T>  0  200  400  Ti  [eV]  T⊥1  T⊥2  T||  <T>  600  400  200 0 200 Vi [km/s] Vx Vy Vz  600  400  200 0 200 Vi [km/s] Vx Vy Vz  102  103  104  Ions  [eV]  102  103  104  104  108  101  102  103  Electrons  [eV]  101  102  103  104  108  4964.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='6  3730.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5  4590.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='9  1910  4865.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='9  3754.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='0  4643.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='3  1911  4765.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5  3776.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1  4694.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='2  1912  0  45  90  [deg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=']  BV  Bn  X [km]  Y [km]  Z [km]  hhmm  2019 Jun 14  a)  a)  b)  b)  c)  c)  d)  d)  e)  e)  f)f)  g)  g)  h)  h)  eV/[eV cm2 s str]  FB shock  FB3  Core  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='"  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='#  B!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' "#,%&  B!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' "#,\'(  TD 4 2  0  2  4  X [RM] 4 2  0  2  4  Y [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Z [RM] 4 2  0  2  4  X [RM]  0  1  2  3  4  S [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Y [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Z [RM] 4 2  0  2  4  X [RM]  0  1  2  3  4  S [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Y [RM] 4 2  0  2  4  X [RM] 4 2  0  2  4  Z [RM] 4 2  0  2  4  X [RM]  0  1  2  3  4  S [RM]  i)  j)  k)  manuscript submitted to Geophysical Research Letters  wind beam energy in Figure 2f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' With increasing 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" and 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='/ in the second half of the core, backstreaming ions disappear from the FOV and the motional electric field drives the reflected ion beam downstream before they reach the spacecraft.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 2D cuts through ion phase space velocity distributions at four timestamps across the event on 14 June 2019 (red arrows in Figure 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The solar wind beam (SW) backstreaming (BS) and accelerated suprathermal (STH) ion populations are labeled on each panel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The dashed black lines show the projection of the magnetic field direction in the plane of the distributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  As the IMF changes direction (dashed black lines on Figure 4 panels) the suprathermal ions ("STH") continue to enter the instrument from roughly the same direction which indicates that these ions are not sourced locally.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' These ions propagate anti-sunward and their energies are  5 0 5 Vy [ x102 km/s] a)  103  104  105  106  107  108  f [s  3/km  6]  b)  5 0 5 Vx [ x102 km/s]  5 0 5 Vy [ x102 km/s] c)  5 0 5 Vx [ x102 km/s]  d)  a) 19:11:09  b) 19:11:17  c) 19:11:25  d) 19:11:33  SW  BS  STH  STH  STH  BS  SW  SW  SW  manuscript submitted to Geophysical Research Letters  above the solar wind beam energy, indicating that they have likely been reflected at the quasi- perpendicular side of the bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 4 Discussions Due to the small curvature radius of the Martial bow shock compared to the upstream ion gyroradius, energization of solar wind ions via multiple shock crossing, as in planar shocks, may not be feasible (urgess, 1987;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Burgess et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2012).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' However, reflected ion trajectories can overlap between quasi-parallel and quasi-perpendicular regions (Moses et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 1988).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Past hybrid simulations and observational studies at Earth have demonstrated that FBs form when a discontinuity convected by the solar wind encounters backstreaming ions in the foreshock region of the quasi-parallel bow shock  (Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2010;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In Figures 1, 2, 3 signatures of ion temperature variations across FBs resembling the observations of FBs at Earth were discussed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' To demonstrate the implications of different size scales at Mars and identify the source region of peculiar ion distributions that cause the temperature variations on transient foreshock structures we developed a test particle model to identify the source and trajectory of ion populations in FB3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' We track a number of solar wind test particle protons in static and uniform electric and magnetic fields, and update the 3D position and velocity of particles at each step by integrating the Lorentz force on the particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Each particle undergoes one specular reflection from the nominal bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Wave-particle interactions and other foreshock effects are not included in this simple model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 3D view of test particle simulation results showing solar wind proton trajectories in static fields across FB3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Mars’s bow shock surface is color coded by 𝜃!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='" (top colorbars), while the color along each trajectory indicates the simulation time (colorbars on the right).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The MAVEN spacecraft position is indicated with a green marker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Panels (a) and (b) correspond to the solar wind conditions at the time of distributions (a) and (c) respectively, in Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The left panel in Figure 5 shows the ion trajectories under upstream conditions at 19:11:09 UT before the FB3 onset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Backstreaming ions appear near the nose of the bow shock, some of which a) b)  4 BIMF -4 Econ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' -2 0 2 MSO M 4美头 0 MS -2 0 2 4 X [RM] MSO M0 2Bn 45 90 130 Time [s] 87 43R 0 MS( -2 Econ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 4 -2 0 Y R MSO M-2 0 MS 2 B IMF X [R 4 MSO M 2 40 Bn 0 45 9 20 109 Time [s] 73 Maven 36 0manuscript submitted to Geophysical Research Letters  have trajectories that cross the MAVEN position.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' These ions are consistent with the "BS" ion population in Figures 4a and b.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In all three events, the ion foreshock and associated parallel temperature enhancements appear with the onset of the discontinuity and are caused by the slow IMF rotation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" This is a distinguishing aspect of Martian FBs from terrestrial cases which are formed when an upstream discontinuity convected by the solar wind encounters backstreaming ions in the foreshock region of Earth's quasi-parallel bow shock (Omidi et al." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2010;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" Figure 5b shows ion trajectories under the solar wind and IMF conditions in the middle of FB3's core at 19:11:25 UT are shown." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Non-solar wind ions that reach MAVEN at this time have been reflected from the quasi-perpendicular regions of the bow shock (Madanian et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020), and after having been accelerated by the motional electric field interact with the upstream discontinuity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' These ions form the "STH" population in Figure 4 b, c, and d causing the increase in the perpendicular ion temperature (Figure 3d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 5 Conclusions We report for the first time detailed analysis of FB events upstream of Mars formed across a rotational discontinuity (FB1), a travelling foreshock (FB2), and a tangential discontinuity (FB3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Waves associated with exospheric pickup ions were either absent or weak during these events.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  For each event we discuss signatures in the magnetic field and plasma moments that are similar and consistent with FB signatures at the terrestrial bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The observations in this study confirm the expectation of FBs being associated with the presence of backstreaming ions and solar wind discontinuities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The results of our test particle model demonstrate that based on the size of the Martian bow shock and the gyro-radius of the ions reflected from the quasi-perpendicular bow shock it is possible for them to travel sufficiently far upstream to contribute to FB formation at Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Even though the Martian foreshock is small compared to that at Earth, backstreaming ion fluxes emerging during slow IMF rotations, and reflected ions from the quasi-perpendicular bow shock that reach the discontinuity can be sufficient to provide the necessary pressure increase for FB formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Embedded solar wind discontinuities are a frequent phenomenon at 1 AU (Neugebauer, 2006;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Schwartz et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2000), and associated foreshock structures have a significant impact on Earth’s magnetosphere and ionosphere (Archer et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Sibeck et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 1999;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2018).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' At Venus, FBs disturb the pressure balance at ionospheric altitudes and uplift the ionospheric heavy ion species, making them more accessible to the pickup process  (Omidi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Given the general similarities in solar wind conditions upstream of Mars and Earth (Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', 2021), and the increase in the solar wind speed and Mach number which favor generation of transient foreshock structures, it is likely that these structures cause disturbances at Mars, particularly due to the lack of a global dipole magnetic field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The global impact of these kinetic scale processes on Mars can be better quantified with multi-point observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' At the time of events discussed here, the Mars Express (MEx) spacecraft was in orbit around Mars, however;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' it was not in a  manuscript submitted to Geophysical Research Letters  good position to provide complimentary information to our analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Future multi-point analyses will benefit from all active spacecraft around Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Acknowledgments We acknowledge the MAVEN contract for support.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' The original funding proposal for this research was not supported by NASA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=" PK's work was supported by DGAPA/PAPIIT grant IN105620." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Open Research All data used in this study are publicly available through the Planetary Data System at https://pds-ppi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='igpp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='ucla.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='edu/mission/MAVEN/, under each instrument name, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='17189/1414178 for magnetometer and https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='17189/1410658 for LPW data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Further information on each data set is included in references in Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  References An, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Formation of Foreshock Transients and Associated Secondary Shocks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=', Ergun, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Delory, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Eriksson, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Westfall, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' The Langmuir Probe and Waves (LPW) Instrument for MAVEN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1007/s11214-015-0194-3 Archer, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Planetary and Space Science, 106 ,56–66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='026 Brain, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', & Modolo, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' In The atmosphere and climate of mars (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Cambridge University Press.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi:10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=', Halekas, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Grebowsky, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=', Mitchell, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Espley, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='Jakosky, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2015, 11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A hot flow anomaly at Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Geophysical Research Letters, 42 (21), 9121– 9127.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1002/2015GL065079 Collinson, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=', Frahm, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Zhang, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Mitchell, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='Jakosky, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2020, 8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Foreshock Cavities at Venus and Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Journal of Geophysical Research: Space Physics, 125 (8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/2020JA028023 Connerney, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' The MAVEN magnetic field investigation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Space Science Reviews, 195 (1-4), 257–291.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' A statistical study of hot flow anomalies using Cluster data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Advances in Space Research, 41 (8), 1286–1291.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='005  manuscript submitted to Geophysical Research Letters  Facskó, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=', Erd ̋os, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' A global study of hot flow anomalies using Cluster multi-spacecraft measurements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' MAVEN Observations of Solar Wind-Driven Magnetosonic Waves Heating the Martian Dayside Ionosphere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' The mars atmosphere and volatile evolution (MAVEN) mission.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Space Science Reviews, 195 (1-4), 3–48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Traveling Foreshocks and Transient Foreshock Phenomena.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='3847/1538-4357/abb249 Liu, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' (2010, 6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Foreshock bubbles and their global magnetospheric impacts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Journal of Geophysical Research: Space Physics, 115 (A6), n/a- n/a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/2009JA014828 Omidi, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Lee, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Sibeck, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Turner, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Liu, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', & Angelopoulos, V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Formation and Topology of Foreshock Bubbles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Journal of Geophysical Research: Space Physics, 125 (9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1029/2020JA028058 Omidi, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Sibeck, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Blanco-Cano, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Rojas-Castillo, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Turner, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Zhang, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', & Kajdiˇc, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2013, 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Dynamics of the foreshock compressional boundary and its connection to foreshock cavities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Journal of Geophysical Research: Space Physics, 118 (2), 823–831.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1002/jgra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='50146 Paschmann, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Haaland, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Sonnerup, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', & Knetter, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2013, 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Discontinuities and Alfv ́enic fluctuations in the solar wind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Annales Geophysicae, 31 (5), 871–887.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5194/angeo-31-871-2013 Rojas-Castillo, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Blanco-Cano, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Kajdiˇc, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', & Omidi, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2013, 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Foreshock compressional boundaries observed by Cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Journal of Geophysical Research: Space Physics, 118 (2), 698–715.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/2011JA017385 Schwartz, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Shock and Discontinuity Normals, Mach Numbers, and Related Parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' In G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Paschmann & P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Daly (Eds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' ), Analysis methods for multi-spacecraft data (Vol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' ISSI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Ion Kinetics in a Hot Flow Anomaly: MMS Observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Geophysical Research Letters, 45 (21).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Conditions for the formation of hot flow anomalies at Earth’s bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/1999JA000320  manuscript submitted to Geophysical Research Letters  Sibeck, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Comprehensive study of the magnetospheric response to a hot flow anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/1998ja900021 Sibeck, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Foreshock Cavities: Direct Transmission Through the Bow Shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Journal of Geophysical Research: Space Physics, 126 (5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/2021JA029201 Sibeck, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Wind observations of foreshock cavities: A case study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Journal of Geophysical Research: Space Physics, 107 (A10).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/2001JA007539 Smith, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' (1973, 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' First observations of foreshock bubbles upstream of Earth’s bow shock: Characteristics and comparisons to HFAs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Hot flow anomaly observed at Jupiter’s bow shock.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Statistical Study of Foreshock Bubbles, Hot Flow Anomalies, and Spontaneous Hot Flow Anomalies and Their Substructures Observed by MMS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content='1029/2021JA030029 Wang, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=' Dayside Magnetospheric and Ionospheric Responses to a Foreshock Transient on 25 June 2008: 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' 2-D Evolution Based on Dayside Auroral Imaging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+page_content=', Wang, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Liu, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', & Lin, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2021, 5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A Foreshock Bubble Driven by an IMF Tangential Discontinuity: 3D Global Hybrid Simulation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='  Geophysical Research Letters, 48 (9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1029/2021GL093068 Yamauchi, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Futaana, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Fedorov, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Frahm, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Winningham, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Dubinin, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Fraenz, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2011, 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Comparison of accelerated ion populations observed upstream of the bow shocks at Venus and Mars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Annales Geophysicae, 29 (3), 511–528.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='5194/angeo-29-511-2011  manuscript submitted to Geophysical Research Letters  Zhang, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Zong, Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Connor, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Delamere, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Facsk ́o, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', Han, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=', .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Yao, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' (2022, 8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Dayside Transient Phenomena and Their Impact on the Magnetosphere and Ionosphere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' Space Science Reviews, 218 (5), 40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
+page_content='1007/s11214-021-00865-0' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ONFJT4oBgHgl3EQfHix_/content/2301.11452v1.pdf'}
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+Prepared for submission to JHEP
+On Bethe equations of 2d conformal field theory
+Tomáš Procházka,a Akimi Watanabeb
+aInstitute of Physics AS CR
+Na Slovance 2, Prague 8, Czech Republic
+bDepartment of Physics, The University of Tokyo
+7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033, Japan
+E-mail: prochazkat@fzu.cz, awatanabe@hep-th.phys.s.u-tokyo.ac.jp
+Abstract: We study the higher spin algebras of two-dimensional conformal field theory
+from the perspective of quantum integrability. Starting from Maulik-Okounkov instanton R-
+matrix and applying the procedure of algebraic Bethe ansatz, we obtain infinite commuting
+families of Hamiltonians of quantum ILW hierarchy labeled by shape of the auxiliary torus.
+We calculate explicitly the first five of these Hamiltonians. Then, we numerically verify that
+their joint spectrum can be parametriezed by solutions of Litvinov’s Bethe ansatz equations
+and we conjecture a general formula for the joint spectrum of all ILW Hamiltonians, based
+on results of Feigin, Jimbo, Miwa and Mukhin.
+There are two interesting degeneration limits, the infinitely thick and the infinitely
+thin auxiliary torus. In one of these limits, the ILW hierarchy degenerates to Yangian or
+Benjamin-Ono hiearchy and the Bethe equations can be easily solved. The other limit is
+singular but we can nevertheless extract local Hamiltonians corresponding to quantum KdV
+or KP hierarchy. Litvinov’s Bethe equations in this local limit provide an alternative to
+Bethe ansatz equations of Bazhanov, Lukyanov and Zamolodchikov, but are more trans-
+parent, work at any rank and are manifestly symmetric under triality symmetry of W1+∞.
+Finally, we illustrate analytic properties of the solutions of Bethe equations in minimal
+models, in particular for Lee-Yang CFT. The analytic structure of Bethe roots is very rich
+as it reflects the whole representation theory of WN minimal models.
+arXiv:2301.05147v1  [hep-th]  12 Jan 2023
+
+Contents
+1
+Introduction
+1
+1.1
+Summary of the paper
+7
+2
+Instanton R-matrix
+8
+3
+Universal R-matrix
+11
+3.1
+Universal R-matrix from fusion
+12
+3.2
+Drinfeľd’s relations I.
+15
+3.3
+Spectral shift and normalization of R(u)
+16
+3.4
+Drinfeľd’s relations II.
+17
+4
+ILW Hamiltonians
+18
+5
+Spectrum and Bethe equations
+23
+5.1
+Normalization and higher Casimir charges
+24
+5.2
+Spectrum of ILW Hamiltonians at q → 0
+25
+5.3
+Ground state eigenvalue of ILW Hamiltonians
+28
+5.4
+Spectrum of (log Hq)j and Bethe ansatz
+29
+5.5
+Feigin-Jimbo-Miwa-Mukhin formula
+31
+6
+Local limit q → 1
+33
+6.1
+Roots of unity and twisted subalgebras
+43
+7
+Examples of solutions
+44
+7.1
+Lee-Yang model
+44
+7.1.1
+Argyres-Douglas minimal models
+44
+7.1.2
+Solutions of Bethe ansatz equations for ∆ = − 1
+5
+48
+7.1.3
+Solutions of Bethe ansatz equations for ∆ = 0
+55
+7.2
+Perturbative expansion at q = 0 and residue formula
+60
+7.3
+Numerical tests in first unitary W4 model
+61
+8
+Outlook
+64
+A Fourier expansions and conformal normal ordering
+69
+A.1 Complex plane
+69
+A.2 Cylinder
+71
+A.3 Example - Virasoro algebra
+73
+B Large u expansion of R-matrix
+74
+B.1
+Mode expansions
+74
+B.2
+Large u expansion of R at N = 1
+75
+B.3
+Large u expansion of universal R
+76
+– i –
+
+C Explicit expressions for ILW Hamiltonians
+77
+C.1 (Quasi-)modular forms
+77
+C.2 Calculation of expectation values in auxiliary space
+78
+C.3 List of expectation values in auxiliary space
+80
+C.4 Third order ILW Hamiltonian
+80
+C.5 Fourth order ILW Hamiltonian
+81
+C.6 Lowest weight expectation value
+84
+D Level 1 test of FJMM
+87
+D.1 Yangian algebra from R-matrix and useful identity
+87
+D.2 Level 1 eigenvalue of Hq(u)
+91
+E Expansions of ILW Hamiltonians in the local limit
+93
+E.1
+ILW Hamiltonians with rational matrix elements
+93
+E.2
+Local expansion of conserved quantities
+96
+F Solutions of Bethe ansatz equations
+99
+F.1
+Lee-Yang, ∆ = 0, level 3
+99
+F.1.1
+Resultant
+99
+F.1.2
+Yangian limit
+100
+F.1.3
+Local limit q → 1
+101
+1
+Introduction
+Two-dimensional conformal field theory owes its solvability to infinite-dimensional symme-
+try algebra, the Virasoro algebra,
+[Lm, Ln] = (m − n)Lm+n + (m − 1)m(m + 1)
+12
+cδm+n.
+(1.1)
+In favourable situations, such as for so-called minimal models, the whole Hilbert space of
+the theory decomposes into a finite number of irreducible representations of two commuting
+copies of the Virasoro algebra. The surprising feature of these representations in contrast
+to representations of complex semisimple algebras is the fact that the analogue of Cartan
+subalgebra is only one-dimensional, spanned by a single generator, L0. All the other gen-
+erators Lm, m ̸= 0 act as ladder operators. As consequence of this, the spectrum of L0 is
+somewhat uninteresting, with all eigenvalues being of the form ∆ + n, n ≥ 0 where ∆ is the
+L0 eigenvalue of the lowest weight vector. The eigenspaces of L0 are highly degenerate, the
+degeneracy going to infinity as n → ∞.
+By contrast, there is a larger class of solvable two-dimensional quantum field theory
+models, whose solvability is due to existence of infinitely many commuting higher conserved
+quantities [1–4]. Examples of such models are the integrable deformations of 2d CFTs,
+where one starts with a 2d conformal field theory in the UV and deforms it by a relevant
+– 1 –
+
+operator.
+Perhaps the most famous example of such a model is the 2d Ising model in
+transverse magnetic field [5] related to the exceptional Lie algebra E8. The question is if
+two-dimensional QFTs with conformal symmetry can be understood from the point of view
+of this more robust framework of integrability. More concretely, we can ask if are there
+other quantities besides L0 that would form an infinite dimensional commutative algebra
+and what their simultaneous spectrum is. Such quantities have been constructed long time
+ago by [6, 7]. Just as Lm are Fourier modes of the local field T(z), the stress-energy tensor,
+we can consider zero Fourier mode of the composite local fields such as (TT)(z) and other
+fields of higher dimension. The requirement of commutativity determines this family of
+operators uniquely up to overall normalization [8]. The first few members are 1
+I1 = T0 = L0 − c
+24
+(1.2)
+I3 = (TT)0 = L2
+0 + 2
+�
+m>0
+L−mLm − c + 2
+12 L0 + c(5c + 22)
+2880
+(1.3)
+I5 = (T(TT))0 + c + 2
+12 (∂T∂T)0
+=
+�
+m1+m2+m3=0
+: Lm1Lm2Lm3 : +
+�
+m>0
+�c + 11
+6
+m2 − 1 − c
+4
+�
+L−mLm
+(1.4)
++ 3
+2
+�
+m>0
+L1−2mL2m−1 − c + 4
+8
+L2
+0 + (c + 2)(3c + 20)
+576
+L0 − c(3c + 14)(7c + 68)
+290304
+.
+Classical limit
+Before proceeding, it is useful to mention the classical limit of this con-
+struction which is well known in the context of the KdV integrable hierarchy [9, 10]. Con-
+sider a second order ordinary differential operators of the form
+L2 ≡ ∂2
+x + u(x)
+(1.5)
+which is just the one-dimensional Schrödinger operator with potential −u(x)2. One may ask
+if there are any deformations of u(x) which do not change the spectrum of the Schödinger
+operator. Clearly one such example is the rigid translation, but in fact there are infinitely
+many other deformations preserving the spectrum. These deformations are organized in the
+form of the KdV hierarchy of partial differential equations. The first non-trivial of these is
+4∂tu = 6u∂xu + ∂3
+xu.
+(1.6)
+As easily shown in the theory of integrable hierarchies, given a potential −u(x), its arbitrary
+finite time evolution according to (1.6) has the same spectrum. There exist infinitely many
+such differential equations forming so-called KdV hierarchy. All these flows commute with
+each other and are isospectral, i.e.
+preserve the spectrum of our Schrödinger operator.
+1Here the double dots denote the oscillator ordering where Fourier modes Lm with larger m are on the
+right. The discussion of conformal normal ordering and its relation to Fourier modes is summarized in
+appendix A.
+2u(x) should be chosen from a suitable class of functions, for example periodic functions or functions
+rapidly decaying at infinity, but for our purposes this choice is not relevant as the discussion is mostly
+algebraic.
+– 2 –
+
+Furthermore, one can think of the space of potentials as being a Hamiltonian system. For
+this one introduces a Poisson bracket on the space of potentials
+{u(x), u(y)} = −∂3
+xδ(x − y) − 4u(x)∂xδ(x − y) − 2∂xu(x)δ(x − y)
+(1.7)
+and finds that the equations of KdV hierarchy are generated by Hamiltonians which are
+integrals of local densities such as
+H1 = 1
+2
+�
+u(x)dx
+(1.8)
+H3 = 1
+8
+�
+u(x)2dx.
+(1.9)
+These two Hamiltonians generate the rigid translations and the flow of (1.6) in the sense
+that
+{H1, u(x)} = ∂xu(x)
+(1.10)
+{H3, u(x)} = ∂tu(x)
+(1.11)
+and similarly for all higher equations of KdV hierarchy. Since all KdV flows are Hamil-
+tonian flows, the Hamiltonians themselves are conserved quantities, i.e. they are spectral
+invariants. Now we see how this classical story parallels the discussion of conserved quan-
+tities in Virasoro algebra (1.2). The Poisson bracket (1.7) written in terms of the Fourier
+modes of u(x) is the classical version (c → ∞ limit) of Virasoro algebra (1.1) and the
+quantum conserved quantities correspond classically to KdV Hamiltonians. The study of
+spectra of Ij is therefore the quantum analogue of the problem of isospectral deformations
+of one-dimensional Schrödinger potentials and its associated classical KdV hierarchy.
+Spectrum and BLZ Bethe ansatz equations
+Despite their natural definition and
+universal appearance in all 2d CFTs, the simulaneous diagonalization of this collection
+of conserved quantities is notoriously difficult. Since in irreducible representations of the
+Virasoro algebra the L0 eigenspaces are finite-dimensional, the diagonalization of Ij is in
+principle reduced to a diagonalization of a finite dimensional matrices. What is missing are
+simple closed-form formulas for their joint spectra. A significant progress in this direction
+was achieved in a series of papers [8, 11, 12] where the authors used the connection of Vira-
+soro algebra to classical KdV hierarchy of differential equations and constructed quantum
+analogues of the monodromy matrices. Traces of these are generating functions of both
+local and non-local conserved quantities associated to Virasoro algebra. These generat-
+ing functions satisfy non-trivial functional equations (such as the analogue of Baxter’s TQ
+relations) as well as non-linear integral equations.
+The next important development happened in the context of ODE/IM correspondence
+[13, 14]. The authors noticed that the same functional equations found earlier by BLZ
+in the context of Virasoro algebra were appearing in the context of ordinary differential
+equations and their spectral and monodromy data. First, the discussion was focused on the
+lowest weight state of the Virasoro representation, but in [15] BLZ managed to generalize
+this correspondence to arbitrary excited states in Virasoro representations. The resulting
+– 3 –
+
+prescription for diagonalizing higher conserved charges in the representations of Virasoro
+algebra is as follows: we start with the second order differential operator
+− ∂2
+z + ϵ2(∆ + ϵ2
+4 − 1
+2)
+z2
++
+1 − �M
+j=1 γj
+z
++
+M
+�
+j=1
+�
+2
+(z − zj)2 +
+γj
+z − zj
+�
++ λzϵ2−2,
+(1.12)
+where ∆ is the conformal dimension of the primary, ϵ is Nekrasov-like parameter parametriz-
+ing the central charge,
+c = 13 − 6(ϵ2 + ϵ−2)
+(1.13)
+and λ, zj and γj are so far free parameters. The coefficient of z−1 is chosen for convenience
+by rescaling the z coordinate. For generic values of ∆ and ϵ we have a differential operator
+with irregular singularities at z = 0 and at z = ∞. To describe the Virasoro excited states
+at level M (in other words L0 eigensubspace with eigenvalue ∆ + M), one allows for M
+additional regular singular points z = zj such that the monodromy of the solutions around
+these singular points is trivial (i.e.
+zj are apparent singularities and we can write two
+linearly independent Frobenius solutions around z = zj of exactly the same form as around
+any regular point). The requirement of absence of monodromy at these M points for all λ
+determines all γj and further imposes M algebraic equations that need to be satisfied by
+M parameters zj,
+�
+k̸=j
+zj(ϵ4z2
+j − (ϵ2 − 2)(2ϵ2 + 1)zjzk + (ϵ2 − 1)(ϵ2 − 2)z2
+k)
+(zj − zk)3
+= (1 − ϵ2)zj − ϵ4∆.
+(1.14)
+Generically there are as many solutions of these equations as there are partitions of M
+[16–18] which agrees with the number of states in generic Virasoro representation at weight
+M. This gives a nice particle-like interpretation of the states in Virasoro representations:
+we can think of states at level M as describing states of M indistinguishable particles. Each
+particle has associated zj ∈ C and the equations (1.14) can be thought of as being Bethe
+equations describing allowed collections of Bethe roots zj corresponding to quantum states,
+analogously to the situation in XXX spin chain or other quantum mechanical integrable
+models with finite number of degrees of freedom. All the local higher spin charges are in
+turn determined as symmetric polynomials of Bethe roots, e.g.
+I1 ⇝ ∆ + M − c
+24
+(1.15)
+I3 ⇝ (∆ + M)2 + (ϵ2 − 2)(2ϵ2 − 1)
+4ϵ2
+(∆ + M) − 4(ϵ2 − 1)
+ϵ4
+M
+�
+j=1
+zj + c(5c + 22)
+2880
+(1.16)
+I5 ⇝ (∆ + M)3 + 6ϵ4 − 17ϵ2 + 6
+8ϵ2
+(∆ + M)2 − 12(ϵ2 − 1)(ϵ2 + 2)
+ϵ4(3ϵ2 + 2)
+(∆ + M)
+�
+j
+zj
++ (ϵ2 − 2)(2ϵ2 − 1)(18ϵ4 − 59ϵ2 + 18)
+192ϵ4
+(∆ + M) + 24(ϵ2 − 1)2
+ϵ6(3ϵ2 + 2)
+�
+j
+z2
+j
+(1.17)
+− (ϵ2 − 1)(ϵ2 + 2)(6ϵ4 − 17ϵ2 + 2)
+2ϵ6(3ϵ2 + 2)
+�
+j
+zj − c(3c + 14)(7c + 68)
+290304
+.
+– 4 –
+
+Despite the fact that Bethe equations (1.14) can be considered as solution to the original
+problem of diagonalizing the local higher spin charges Ij, they have their drawbacks. First
+of all, the Virasoro algebra is a rank 2 member of a larger family of vertex operator algebras,
+so called WN algebras, all of which can be embedded in two-parametric family called W∞
+[19–21].
+The representation theory of W∞ simplifies considerably if we add additional
+Heisenberg algebra �
+u(1), resulting in algebra called W1+∞. The bases of representation
+spaces of W1+∞ are labeled by combinatorial objects such as N-tuples of Young diagrams
+or 3d Young diagrams (plane partitions). It is not obvious from the structure of (1.14) how
+to generalize these to other WN algebras. In [22] the construction of monodromy matrices
+and Q-operators was generalized to W3. In [23] the authors considered the generalization
+of system (1.14) based on work of Feigin-Frenkel [24] whose general construction allows in
+principle to write the analogue of (1.14) for all N > 2. But all these systems of Bethe
+equations become increasingly complicated as the rank increases and in particular at fixed
+level the number of unknowns and equations increases with the rank N. Furthermore, they
+do not manifest the discrete symmetries (in particular triality symmetry) of the algebra.
+Litvinov’s Bethe ansatz equations
+In this work we consider another system of Bethe
+ansatz equations introduced in [25],
+q
+N
+�
+l=1
+xj + al − ϵ3
+xj + al
+�
+k̸=j
+(xj − xk + ϵ1)(xj − xk + ϵ2)(xj − xk + ϵ3)
+(xj − xk − ϵ1)(xj − xk − ϵ2)(xj − xk − ϵ3) = 1,
+j = 1, . . . , M.
+(1.18)
+Here ϵj parameters are Nekrasov-like parameters parametrizing the rank and central charge
+of W∞ algebra. Parameters aj on the other hand parametrize the weights of the lowest
+weight vector (generalizing ∆ in the case of Virasoro). Finally, q is a deformation parameter
+to be discussed later. There are several important differences between (1.14) and (1.18).
+First of all, the interaction between individual Bethe roots in (1.14) is additive while in
+(1.18) this is controlled by
+ϕ(x) = (x + ϵ1)(x + ϵ2)(x + ϵ3)
+(x − ϵ1)(x − ϵ2)(x − ϵ3)
+(1.19)
+which is the structure constant of W1+∞ [26, 27]. It has also a natural interpretation of a
+scattering phase (see for instance the TBA equations for elliptic Calogero-Moser system of
+[28]). The first product in (1.18) controls interaction of Bethe roots with background fields
+which in our situation are just the lowest weights of W1+∞ representation.
+A new ingredient is the twist parameter q. It can be interpreted in several ways and has
+an important rôle in the following. From point of view of the representation theory, it con-
+trols which infinite dimensional abelian subalgebra of W1+∞ we are diagonalizing, i.e. which
+integrable structure we are considering. For generic values of q the associated Hamiltonians
+are those of intermediate long wave equation and its hierarchy [25, 29–33]. The limits q → 0
+and q → ∞ correspond to Yangian limits (Benjamin-Ono limits), where the diagonalized
+abelian subalgebra is the abelian subalgebra manifest in the Yangian presentation of the
+algebra [26, 27]. The advantage of this subalgebra is that it is easily diagonalized in terms
+– 5 –
+
+Figure 1: R-matrix as a defect (blue) coupling two chiral CFTs, the quantum space (left) is
+considered to be on a cylinder while the auxiliary space (right) is torus with shape controlled
+by parameter q. The family of Hamiltonians acting on the cylinder on the left is controlled
+by the shape of the auxiliary torus on the right. In our construction, the torus comes with
+a choice of a cycle, so it makes sense to talk about thick or thin torus. By a thin torus we
+mean a torus glued from a long cylinder equipped with a cycle. The limits of infinitely thick
+or thin torus correspond to Yangian-Benjamin-Ono family (glued from a long cylidner) or
+Korteweg–De Vries-Kadomtsev–Petviashvili-Bazhanov-Lukyanov-Zamolodchikov family of
+Hamiltonians (glued from a short cylinder). For generic shapes q we get Hamiltonians from
+the family of intermediate long wave equation.
+of combinatorics of Young diagrams (or plane partitions). This is reflected in (1.18) by the
+fact that q → 0 or q → ∞ limit Bethe roots become zeros of numerators or denominators,
+i.e. Litvinov’s Bethe equations factorize into linear factors and can be easily solved. Disad-
+vantage of the Yangian limit is the fact that the higher conserved quantities are non-local
+from the CFT point of view, i.e. they cannot be written as zero Fourier modes of local
+currents. To diagonalize the local charges (quantum KdV or KP charges studied by BLZ),
+one needs to consider the limit q → 1 which is however very singular. One of the aims of
+this article is to study concretely the behaviour of various quantities in the local limit and
+extract information about local charges. There are other rôles of parameter q. From spin
+chain point of view it is simply the twist parameter, controlling shape of the auxiliary space.
+Concretely, q parametrizes the complex structure of the auxiliary Riemann surface which
+is introduced as a regulator of the trace over auxiliary space. This trace would otherwise
+not be defined since in our situation the auxiliary space is infinite dimensional. Finally,
+from point of view of numerical solution of equations (1.18), q appears as a very natural
+homotopy parameter, allowing us to smoothly connect the solvable Yangian limit with the
+physically interesting local BLZ limit. As we will see, there is very interesting analytic
+structure of solutions of (1.18) over q-plane.
+– 6 –
+
+1.1
+Summary of the paper
+The aim of this work is to apply the procedure of algebraic Bethe ansatz [34, 35] to explicitly
+construct first few commuting quantum ILW Hamiltonians, study their spectra in terms of
+Litvinov’s Bethe ansatz equations as well as their local q → 1 limit.
+More concretely, we start from Maulik-Okounkov instanton R-matrix [36–39] for a
+pair of free bosons.
+Working in the large spectral parameter expansion, we fuse these
+and calculate first few coefficients of the universal R-matrix, which has the form of the
+exponential of integral of local currents in two copies of W1+∞.
+In the next step we
+specialize the auxiliary space to be the one of single free boson and calculate the trace to get
+the transfer matrix acting in the quantum space. Since the free boson Fock space is infinite
+dimensional, we have to regularize the trace. Following [25], we choose the regulator to be
+of the form qL0. This choice effectively puts the auxiliary boson on a torus with modular
+parameter q, without spoiling the commutativity of the resulting ILW Hamiltonians. This
+setup is illustrated in Figure 1. The left part of the diagram represents the quantum space
+which we identify with a conformal field theory with W1+∞ symmetry living on a cylinder.
+The right part of the diagram shows the auxiliary space which is a torus. We will mostly
+restrict to the situation where the theory associated with the auxiliary space is a single free
+boson. The R-matrix is an operator acting on product of both spaces so we can think of
+it as being a codimension 2 defect inserted along the product of two blue circles. This is
+somewhat similar to the construction of quantum transfer matrices in [8, 11, 12], but in
+their setup, the auxiliary space is a finite dimensional representation space of underlying
+quantum group Uq(sl(2)), 3 while in our setup the underlying symmetry algebra is W1+∞
+or equivalently the Yangian of �gl(1).
+Technically the hardest part of the article is the evaluation of the trace. We calculated
+first five non-trivial ILW Hamiltonians. Assuming validity of Litvinov’s conjectured Bethe
+ansatz equations, i.e. the fact that the spectra of ILW Hamiltonians can be written in terms
+of symmetric functions of solutions of (1.18), we are able to determine exact expressions
+for eigenvalues of all five ILW Hamiltonians that we found. These are in turn matched to a
+conjectural formula analogous to a formula by Feigin, Jimbo, Miwa and Mukhin [40] that
+was proven in the related context of quantum toroidal algebra. Our expressions for the
+spectra of first five ILW Hamiltonians perfectly agree with the conjectural formula.
+In the next part, we study carefully the local (q → 1) BLZ/KdV/KP limit of Bethe
+ansatz equations. This limit is quite singular, because it is exactly the limit of removal of
+the regulator. Both ILW Hamiltonians as well as most solutions of Bethe ansatz equations
+become singular in this limit.
+But surprisingly the singularities in Bethe roots can be
+associated to excitations of Heisenberg subalgebra of W1+∞. The remaining Bethe roots,
+finite in q → 1 limit, are associated to more interesting W∞ subalgebra. Using our explicit
+expressions for first five ILW Hamiltonians, we show how to disentangle the Heisenberg
+part from W∞ conserved quantities and give formulas for conserved quantities I2 and I3
+3The authors of [8, 11, 12] also consider infinite dimensional auxiliary vector spaces but these do not
+have an interpretation of another copy of QFT - these representations can be thought of as highest weight
+representations of continuous spin.
+– 7 –
+
+generalizing (1.2) from Virasoro algebra to W∞.
+We conclude by some examples of solutions of Bethe ansatz equations. We study both
+analytically and numerically the solutions at lower levels in Lee-Yang model (chiral algebra
+associated to (A1, A2) Argyres-Douglas model) and in the first unitary minimal W4 model.
+The analytic structure of Bethe roots as functions of parameter q is extremely rich, as it
+captures the representation theory of WN minimal models.
+2
+Instanton R-matrix
+In this section, we will review the construction of Maulik and Okounkov’s instanton R-
+matrix [36, 38, 39, 41]. We will follow the notation and conventions of [39]. Consider a
+collection of N independent free bosons Jj(z) (ˆgl(1) Heisenberg vertex operator algebras)
+with OPE
+Jj(z)Jk(w) ∼
+δjk
+(z − w)2 + reg.
+(2.1)
+where j or k label the free bosons, i.e. take values from 1 to N. To each of these currents
+we associate Miura operator
+α0∂z + Jj(z)
+(2.2)
+where α0 is a fixed complex number. Composing these first order differential operators
+results in Nth order differential operator with coefficients that are local fields. There are
+no ordering ambiguities when we multiply the fields since the Jj(z) coming from different
+factors of the product commute. The subalgebra generated by the coefficients of Nth order
+differential operator turns out to be closed under operator product expansions.
+It is a
+product of diagonal ˆgl(1) Heisenberg algebra with WN algebra and the construction we
+just reviewed is the simplest free field representation of WN [42–44]. In the case of N = 2
+(i.e. starting with just two free bosons) the algebra W2 goes under the name of Virasoro
+algebra. Decoupling the diagonal ˆgl(1) current in this case gives a representation of Virasoro
+algebra in terms of one free boson J1 − J2 and in the classical limit this is the well-known
+Miura transformation (studied originally in the context of KdV hierarchy).
+Note that the composition of elementary Miura operators (2.2) to construct WN algebra
+is analogous to construction of gl(M) Yangian from its level 1 representation. Fusing N
+of these using the Yangian coproduct, we get level N representation of gl(M) Yangian. In
+the context of integrable spin chains N is related to the length of the spin chain. In CFT
+N is related to the maximal spin of the generating fields of the algebra. Yangian of gl(M)
+is obtained by fusion of general number of level 1 representation (corresponding to spin
+chains of arbitrary length) and the analogous notion in CFT is the algebra W1+∞ which
+has generators of all spins [19, 20]. All WN algebras can be obtained by truncation from
+W1+∞. The construction goes through essentially unmodified if we replace ˆgl(1) by ˆgl(M)
+in which case we obtain a matrix-valued W1+∞ algebra (Yangian of affine gl(M)) [45, 46].
+In order to construct WN generators as differential polynomials in ˆgl(1) currents Jj,
+we need to multiply the elementary operators (2.2) in certain order. The resulting algebra
+is independent of the order, but the way it sits in the Fock space of N free bosons depends
+on the order of the elementary Miura factors. Maulik-Okounkov R-matrix is the similarity
+– 8 –
+
+transformation that connects these embeddings [36]. Since any permutation is a composition
+of transpositions, it is enough to study the case of N = 2. In this case, R is an operator
+acting on product of two ˆgl(1) Fock spaces. Up to an overall normalization, it is uniquely
+defined by the property
+R(α0∂ + J1)(α0∂ + J2) = (α0∂ + J2)(α0∂ + J1)R.
+(2.3)
+Commuting the derivatives to the right, we see that this is equivalent to
+R(α2
+0∂2+α0(J1+J2)∂+(J1J2)+α0J′
+2)R−1 = (α2
+0∂2+α0(J1+J2)∂+(J1J2)+α0J′
+1). (2.4)
+Since R does not depend on the coordinate of the local fields (it is expressible purely in
+terms of their Fourier modes), in order for this equation to be satisfied the coefficients of
+each power of ∂ must be equal. The coefficients of ∂2 agree trivially. From the coefficients
+of ∂1 we see that R must commute with the total current J1 + J2. This means that it has
+to be constructed out of modes of the difference current
+J− = α0(J1 − J2).
+(2.5)
+The remaining restriction therefore comes from the equality of coefficients of ∂0. Written
+in terms of J− (and simplifying using the commutativity with J1 + J2), this amounts to
+R
+�1
+2(J−J−) + α2
+0∂J−
+�
+R−1 = 1
+2(J−J−) − α2
+0∂J−
+(2.6)
+This is the main equation that defines Maulik-Okounkov R-matrix in terms of local fields.
+Given an action of R on the vacuum of J− Fock space (which determines the overall
+normalization of R), this equation determines level by level the action of R on all other
+states in the Fock space.
+One can also solve the equation (2.6) perturbatively in large spectral parameter [38].
+In CFT, the rôles of the spectral parameter are the zero modes of the ˆgl(1) currents [39]
+which are central. For this reason, in [38, 39] the zero mode of J− was treated differently
+than the remaining modes. Various terms in perturbative expansion of R were written in
+terms of oscillators not involving the zero mode of J−. In the analysis that we will do
+here we will keep this zero mode. Therefore, we will introduce the spectral parameter u by
+performing a constant shift (which is an automorphism of the Heisenberg algebra)
+J−(z) → J−(z) + α0u.
+(2.7)
+This introduces certain redundancy which we can use as consistency check of our calcula-
+tions. The equation (2.6) becomes
+R
+�
+α0uJ− + 1
+2(J−J−) + α2
+0∂J−
+�
+=
+�
+α0uJ− + 1
+2(J−J−) − α2
+0∂J−
+�
+R
+(2.8)
+This is the equation that we can solve perturbatively at large u. It turns out that the large
+u expansion of R simplifies if we take a logarithm of R. We therefore write
+R(u) = exp
+�
+r(1)
+α0u + r(2)
+α2
+0u2 + . . .
+�
+≡ exp r(u)
+(2.9)
+– 9 –
+
+Here r(j) turn out to be zero modes of certain local currents constructed of J− (this is the
+reason for taking the logarithm of R) [25].
+At leading order u0 we need to solve
+�
+r(1), J−
+�
++ 2α2
+0∂J− = 0
+(2.10)
+whose solution is
+r(1) = −1
+2(J−J−)0.
+(2.11)
+This is a unique solution that is a zero mode of a local operator of dimension 2. If we relax
+the requirement of dimension 2, we can add to r(1) a linear combination of the zero mode
+of J− and of the identity operator (which are both central). This freedom in turn can be
+absorbed into u-dependent normalization of R which is not fixed by (2.6).
+At next order u−1 we have
+�
+r(2), J−
+�
++ 1
+2
+�
+r(1)2, J−
+�
++
+�
+r(1), 1
+2(J−J−)
+�
++ α2
+0
+�
+r(1), ∂J−
+�
+= 0
+(2.12)
+which simplifies to
+�
+r(2), J−
+�
++
+�
+r(1), 1
+2(J−J−)
+�
+= 0
+(2.13)
+with solution
+r(2) = 1
+6(J−(J−J−))0
+(2.14)
+(which is again unique zero mode of a local field up to addition of a constant or of the zero
+mode of J−). Note that all terms in (2.12) that were not commutators canceled. This had
+to be the case as follows from the ad-exp identity
+e[r,·]
+�
+α0uJ− + 1
+2(J−J−) + α2
+0∂J−
+�
+= α0uJ− + 1
+2(J−J−) − α2
+0∂J−.
+(2.15)
+Order u−2 terms of this equation are
+�
+r(3), J−
+�
++ 1
+2
+�
+r(1),
+�
+r(2), J−
+��
++ 1
+2
+�
+r(2),
+�
+r(1), J−
+��
++ 1
+6
+�
+r(1),
+�
+r(1),
+�
+r(1), J−
+���
++
++
+�
+r(2), 1
+2(J−J−) + α2
+0∂J−
+�
++ 1
+2
+�
+r(1),
+�
+r(1), 1
+2(J−J−) + α2
+0∂J−
+��
+= 0
+(2.16)
+whose unique local solution is
+r(3) = − 1
+12(J−(J−(J−J−)))0 + α2
+0(1 + 2α2
+0)
+12
+(∂J−∂J−)0
+(2.17)
+up to addition of central terms. Writing this in terms of creation-annihilation normal order
+(using expressions in appendix B.1), we find
+r(3) = − 1
+12 : J4
+− :0 +α2
+0
+12 : J2
+− :0 − α4
+0
+144 + α2
+0(1 + 2α2
+0)
+12
+: ∂J−∂J− :0 −α2
+0(1 + 2α2
+0)
+12
+α2
+0
+60 (2.18)
+– 10 –
+
+in agreement with mode expansions (3.44) of [39]4.
+Employing the identity (2.15), we can find perturbative solution for r(j) much more
+efficiently than by manipulating the mode expansions as was done by hand in [38, 39]. All
+we need to do is to calculate multiple commutators of zero mode of a local operator with
+another local operator. As discussed in appendix A, this in turn amounts to taking the first
+order pole of OPE between two local operators which can be done very quickly using the
+package OPEdefs by Thielemans [47]. In this way, the r(j) can be found to rather high order
+(j ∼ 20) in few seconds. The first few of these expressions are given in appendix B.2. Note
+that since in terms of Fourier modes on cylinder the zero mode of total derivative vanishes,
+there is an ambiguity in writing r(j) as zero modes of local operators – although the zero
+mode is well-defined and uniquely determined, the local operator is not.
+The most important property of R whose construction we just reviewed is the fact that
+it satisfies the Yang-Baxter equation
+R12(u1 − u2)R13(u1 − u3)R23(u2 − u3) = R23(u2 − u3)R13(u1 − u3)R12(u1 − u2) (2.19)
+In order to understand origin of this equation, we need to consider three Fock spaces and
+two ways how to change the order 123 → 321. The operator constructed out of Fourier
+modes of fields that is exponential of local field is unique up to central terms. Therefore,
+(2.19) has to hold up to possible difference in normalization.
+As usual in the context of quantum integrability, once we have a solution of Yang-
+Baxter equation (2.19), the procedure of algebraic Bethe ansatz can be immediately applied
+to construct commuting Hamiltonians and study their spectrum. This is what we will do
+in the following sections.
+3
+Universal R-matrix
+In this section we would like to find an expression for R for representations not restricted
+to Yangian level 1 (i.e. we are interested in fields of spin greater than 1). In order to do
+that, we will take the elementary level one R-matrices defined in the previous section and
+fuse them N times in the left factor and ¯N times in the right factor. Having an expression
+for general N and ¯N, this is equivalent to knowing a universal R-matrix of W1+∞. This
+R-matrix will satisfy Drinfeľd’s relations
+R∆(x)R−1 = ∆op(x)
+(3.1)
+(∆ ⊗ 1)(R) = R13R23
+(3.2)
+(1 ⊗ ∆)(R) = R13R12
+(3.3)
+as we will verify perturbatively in large central charge expansion. Here x is any local field
+(or its Fourier mode) and ∆(x) is the coproduct [20].
+4This agrees with (3.47) if the parentheses in [39] are understood as creation-annihilation normal order-
+ing.
+– 11 –
+
+R1¯1
+R2¯1
+R3¯1
+R4¯1
+R5¯1
+R1¯2
+R2¯2
+R3¯2
+R4¯2
+R5¯2
+R1¯3
+R2¯3
+R3¯3
+R4¯3
+R5¯3
+R1¯4
+R2¯4
+R3¯4
+R4¯4
+R5¯4
+Figure 2: Illustration of the fusion of elementary R-matrices for (N, ¯N) = (5, 4). We
+should multiply Rj¯k starting from the upper left corner and proceeding all the way to the
+lower right corner. Since the elementary factors that are neither on same row nor on the
+same column commute, the multiplication column-by-column or row-by-row gives the same
+answer.
+3.1
+Universal R-matrix from fusion
+We start with N + ¯N copies of ˆgl(1) Fock space, labeled by Hj, j = 1, . . . , N and H¯k,
+k = 1, . . . , ¯N. We will denote the elementary R-matrix acting on Hj ⊗ H¯k by Rj¯k. The
+fused R-matrix is then given by a product of N × ¯N terms
+R ≡ R1 ¯
+NR2 ¯
+N · · · RN ¯
+NR1N−1 · · · RNN−1 · · · R1¯2 · · · RN¯2R1¯1R2¯1 · · · RN¯1
+=
+N
+�
+−−→
+j=1
+¯
+N
+�
+←−−
+k=1
+Rj¯k.
+(3.4)
+The factors corresponding to Hj are multiplied from left to right while the factors corre-
+sponding to H¯k are multiplied in the opposite direction. This is necessary in order for the
+result to be expressible in terms of WN × W ¯
+N generators (this is also consistent with the
+difference between Drinfeľd’s relations (3.2) and (3.3)). This is illustrated in Figure 2. We
+multiply the individual factors starting from the upper left corner and proceeding all the
+way to the lower right corner, with every step going either right or down. All the factors
+appearing to the left or above any given elementary R-matrix must appear in the product
+on the left. This is the only restriction on the order of factors in the product and any two
+orders satisfying this restriction are equivalent due to commutativity of Rj¯k which sit on
+different rows and columns.
+Since every elementary R-matrix is of the form of an exponential of a zero mode of
+local fields, and since commutator of two zero modes of local fields is again a zero mode of
+a local field, Baker-Campbell-Hausdorff formula guarantees that the fused R-matrix is of
+– 12 –
+
+this form as well. Furthermore, we can use the Baker-Campbell-Hausdorff formula to find
+the large spectral parameter expansion of the fused R-matrix. We will denote the fused
+R-matrix by R(u) (in contrast to R(u) which denotes the elementary R-matrix). The large
+spectral charge expansion of R(u) is of the form
+R(u) = exp
+�
+r(1)
+u
++ r(2)
+u2 + r(3)
+u3 + . . .
+�
+≡ exp r(u)
+(3.5)
+Unlike in the case of (2.9) here we absorb the powers of α0 into coefficients r(j) (the former
+was kept to be compatible with conventions of [39]). As before, each r(j) will be zero mode
+of a local field of engineering dimension j + 1. Furthermore, this local field is determined
+uniquely up to total derivatives.
+In order to determine the coefficients r(j) in the large spectral charge expansion of
+R(u), we use the Baker-Campbell-Hausdorff formula generalized to an arbitrary number of
+factors in the product, i.e. the expansion
+log(eX1eX2 · · · eXN ) =
+�
+j
+Xj + 1
+2
+�
+j<k
+[Xj, Xk]
++ 1
+12
+�
+j<k
+([Xj, [Xj, Xk]] + [[Xj, Xk] , Xk])
+(3.6)
++ 1
+6
+�
+j<k<l
+([Xj, [Xk, Xl]] + [[Xj, Xk] , Xl]) + . . .
+and similar but more complicated expressions at higher orders. It is important that every-
+thing is expressed in terms of repeated commutators, so in particular assuming that the
+elementary R-matrix was of the form of exponential of zero mode of a local field, the same
+will be automatically true for R(u). For the leading coefficient, we find
+r(1) = −α0
+2
+�
+(j,¯j)
+((Jj − J¯j)(Jj − J¯j))0
+= −α0 ¯N
+2
+�
+j
+(JjJj)0 − α0N
+2
+�
+¯j
+(J¯jJ¯j)0 + α0
+�
+j,¯j
+(JjJ¯j)0
+(3.7)
+where j and ¯j are considered as independent summation variables. Using the expressions
+for free field representations of WN generators (for example section 3.1 in [20]), we can
+identify this with
+r(1) = −α0 ¯N
+�
+−U2 + 1
+2(U1U1)
+�
+0 − α0N
+�
+− ¯U2 + 1
+2( ¯U1 ¯U1)
+�
+0 + α0(U1 ¯U1)0
+= −α0 ¯NT0 − α0N ¯T0 + α0(U1 ¯U1)0
+(3.8)
+where
+T = −U2 + 1
+2(U1U1) + (N − 1)α0
+2
+∂U1
+= 1
+2
+�
+j
+(JjJj) + α0
+2
+�
+j
+(N + 1 − 2j)∂Jj
+(3.9)
+– 13 –
+
+is the total stress-energy tensor of the left copy of ˆgl(1) × WN and similarly for ¯T. Here
+and in the following we use bars for all quantities associated to the right factor, i.e. the
+local fields Uj satisfy the OPEs of ˆgl(1) × WN with parameter α0 [20] while the fields ¯Uj
+satisfy OPEs of an independent ˆgl(1) × W ¯
+N with parameter α0. Note that by construction
+both algebras have the same value of the parameter α0. This is equivalent to having same
+Kapustin-Witten parameter ψ in the notation of [48, 49] or in the language of [26, 27] having
+the same Nekrasov-like parameters (h1, h2, h3) up to an overall scale. This constraint reflects
+the fact that the fusion operation using W1+∞ coproduct exists at fixed value of α0 while
+acting additively in N [20].
+Although the fusion construction that we are discussing is assuming N and ¯N to be
+positive integers, the resulting expressions are written as expressions in terms of local fields
+with coefficients that are rational functions of N, ¯N and α0. We can therefore interpret
+them as expressions in W∞, without any restrictions on N and ¯N [20]. In the following, we
+will freely tranition between WN and W∞ picture, depending on what is more convenient.
+At the next order, it follows from the Baker-Campbell-Hausdorff formula that
+r(2) = 1
+α2
+0
+�
+j,¯j
+r(2)
+(j,¯j) +
+1
+2α2
+0
+�
+(j,¯j)<(k,¯k)
+�
+r(1)
+(j,¯j), r(1)
+(k,¯k)
+�
+.
+(3.10)
+Here the notation (j, ¯j) < (k, ¯k) is related to our fixed order of the vertices in Figure 2, e.g.
+we can sum over all pairs that have either (j < k) or (j = k and ¯k < ¯j) – remember the
+opposite order of the barred indices. Plugging in the expressions for r(j), this equals
+r(2) = α0
+6
+�
+j,¯j
+�
+(Jj(JjJj)) − 3((JjJj)J¯j) + 3(Jj(J¯jJ¯j)) − (J¯j(J¯jJ¯j))
+�
+0
++ α2
+0
+8
+�
+(j,¯j)<(k,¯k)
+�
+(JjJj) − 2(JjJ¯j) + (J¯jJ¯j)0, (JkJk) − 2(JkJ¯k) + (J¯kJ¯k)0
+�
+= α0 ¯N
+6
+�
+j
+(Jj(JjJj))0 + α2
+0 ¯N
+2
+�
+j<k
+(∂JjJk)0 − α0N
+6
+�
+¯j
+(J¯j(J¯jJ¯j))0
+(3.11)
+− α2
+0N
+2
+�
+¯j<¯k
+(∂J¯jJ¯k)0 − α0
+2
+�
+j,¯j
+((JjJj)J¯j)0 + α0
+2
+�
+j,¯j
+(Jj(J¯jJ¯j))0
+− α2
+0
+2
+�
+j
+�
+¯k
+( ¯N + 1 − 2¯k)(∂JjJ¯k)0 + α2
+0
+2
+�
+j
+(N + 1 − 2j)
+�
+¯k
+(Jj∂J¯k)0.
+Defining a local spin 3 field
+φ3 = U3 − (U1U2) + 1
+3(U1(U1U1)) − (N − 2)α0
+2
+U ′
+2
++ (N − 1)α0
+2
+(U ′
+1U1) + N2α2
+0 − Nα2
+0 + 4α2
+0 + 2
+12
+U ′′
+1
+= 1
+3
+�
+j
+(Jj(JjJj)) + α0
+2
+�
+j<k
+(∂JjJk − Jj∂Jk)
+(3.12)
++ α0
+2
+�
+j
+(N + 1 − 2j)(∂JjJj) + 1
+6
+�
+j
+∂2Jj
+– 14 –
+
++ α2
+0
+12
+�
+j
+(3j2 + 3(N + 1 − j)2 − (N + 1)(2N − 1))∂2Jj
+we finally find
+r(2) = α0 ¯N
+2
+φ3,0 − α0(T ¯U1)0 + α0(U1 ¯T)0 − α0N
+2
+¯φ3,0.
+(3.13)
+Note that the last two lines in the free field representation of φ3 are total derivatives so they
+do not contribute to the zero mode and therefore to r(2), but this choice of φ3 will slightly
+simplify the expression for r(3). If we require r(j) to be a zero mode of a field of engineering
+dimension j + 1, the only ambiguity is in total derivatives, which do not contribute to the
+zero mode. We also see that if we did not choose the order of the barred indices in (3.4) to
+be the opposite of the order of the unbarred indices, we would not be able to write r(2) in
+terms of ˆgl(1) × W ¯
+N generators – the sign of
+�
+¯j<¯k
+∂J¯jJ¯k
+(3.14)
+would be wrong, and it is the sign of this term that reflects the way we ordered our free
+bosons J¯j.
+The calculation could be alternatively done entirely in terms of oscillators, but such a
+calculation is computationally harder (while leading to the same result). We can use the
+free field representation and fusion as just described to proceed to higher orders. In this
+way we calculated r(3) and r(4). The expressions for these are given in the appendix B.3.
+3.2
+Drinfeľd’s relations I.
+It is easy to verify Drinfeľd’s relations (3.2) and (3.3) perturbatively in large u. Since the
+coproduct is a homomorphism of algebras, we can take the logarithm of (3.2),
+(∆ ⊗ 1)r(u) = log [exp (r13(u)) exp (r23(u))]
+(3.15)
+and apply the BCH formula on the right-hand side. Expanding at large u, we find for the
+first few orders
+(∆ ⊗ 1)(r(1)(u)) = r(1)
+13 (u) + r(1)
+23 (u)
+(3.16)
+(∆ ⊗ 1)(r(2)(u)) = r(2)
+13 (u) + r(2)
+23 (u) + 1
+2
+�
+r(1)
+13 (u), r(1)
+23 (u)
+�
+(3.17)
+(∆ ⊗ 1)(r(3)(u)) = r(3)
+13 (u) + r(3)
+23 (u) + 1
+2
+�
+r(1)
+13 (u), r(2)
+23 (u)
+�
++ 1
+2
+�
+r(2)
+13 (u), r(1)
+23 (u)
+�
++ 1
+12
+�
+r(1)
+13 (u),
+�
+r(1)
+13 (u), r(1)
+23 (u)
+��
++ 1
+12
+��
+r(1)
+13 (u), r(1)
+23 (u)
+�
+, r(1)
+23 (u)
+�
+(3.18)
+etc. Unlike in the previous section, here we only need the two-variable BCH formula to
+evaluate the right-hand side, but for the left-hand side we need to know the coproduct of
+ˆgl(1) × WN generators [20].
+Let us explicitly verify the first of these relations. We need to calculate the coproduct
+of (3.8) in the first factor. We have (see section 3.8 in [20])
+∆(N) = N(1) + N(2)
+(3.19)
+– 15 –
+
+∆(U1) = U(1)1 + U(2)1
+(3.20)
+∆(U2) = U(1)2 + U(2)2 + (U(1)1U(2)1) + α0N(1)∂U(2)1
+(3.21)
+so
+∆(T) = T(1) + T(2) + α0N(2)
+2
+∂U(1)1 − α0N(1)
+2
+∂U(2)1
+(3.22)
+and
+(∆ ⊗ 1)(r(1)(u)) = −α0N(3)∆(T0) − α0∆(N)(T(3))0 + α0(∆(U1)U(3)1)0
+= −α0N(3)
+�
+(T(1))0 + (T(2))0 + α0N(2)
+2
+(∂U(1)1)0 − α0N(1)
+2
+(∂U(2)1)0
+�
+− α0(N(1) + N(2))(T(3))0 + α0(U(1)1U(3)1)0 + α0(U(2)1U(3)1)0
+(3.23)
+while the right-hand side is
+r(1)
+13 (u) + r(1)
+23 (u) = −α0N(3)(T(1))0 − α0N(1)(T(3))0 + α0(U(1)1U(3)1)0
+− α0N(3)(T(2))0 − α0N(2)(T(3))0 + α0(U(2)1U(3)1)0.
+(3.24)
+Since the zero mode of a total derivative vanishes, we see that both of these expressions
+agree.
+We may similarly verify these two Drinfeľd’s relations up to order u−4 involving r(4).
+We calculated these coefficients explicitly by fusing the elementary R-matrices (and explicit
+expressions for these are given in appendix B.3). Since the formula for comultiplication of
+generators of W1+∞ is known [20], we may as well use Drinfeľd’s relations to determine
+higher r(j) coefficients. In this way we determined r(5) and r(6), but these are too long to list
+here (the expression for r(6) has 22 pages in Mathematica). The calculation using Drinfeľd’s
+relations is more efficient way to determine r(j) than using the free field representations as
+was done in the previous section, especially because the BCH formula for large number of
+variables is complicated.
+3.3
+Spectral shift and normalization of R(u)
+The algebras ˆgl(1) × WN have continuous automorphisms shifting the (central) zero mode
+of ˆgl(1) generator by a constant and leaving the WN part intact. In the quadratic basis
+of generators of the algebra that we are using, the ˆgl(1) and WN factors are mixed, so in
+particular all Uj fields transform under this transformation linearly as
+Uj → Sγ(Uj) ≡
+j
+�
+k=0
+(N − j + 1)k
+γk
+k! Uj−k
+(3.25)
+where (N)k is the raising factorial (Pochhammer symbol) and γ is a parameter of the
+symmetry transformation. Under such transformation of the left sector, the coefficients r(j)
+transform as
+r(j) →
+j−1
+�
+k=0
+�j − 1
+k
+�
+(−γ)kr(j−k) + (−γ)j
+j
+α0( ¯NU1 − N ¯U1)0 − (−γ)j+1
+j(j + 1) α0N ¯N1
+(3.26)
+– 16 –
+
+This is almost equivalent to a shift of the spectral parameter u:
+r(u) →
+∞
+�
+j=1
+r(j)
+(u + γ)j + log
+�
+u
+u + γ
+�
+α0( ¯NU1 − N ¯U1)0 +
+�
+(u + γ) log
+�
+u
+u + γ
+�
++ γ
+�
+α0N ¯N
+(3.27)
+The reason why this is not simply translation of u parameter is that in (3.5) and in similar
+expansion of the elementary R-matrix we chose a specific (unnatural) normalization of
+R(u). We can always rescale R(u) (or shift r(u)) by any central function, i.e. function of
+N, ¯N, α0 and of zero modes of U1 and ¯U1. If we define
+˜r(u) ≡ r(u) − log u α0( ¯NU1 − N ¯U1)0 − (u log u − u)α0N ¯N,
+(3.28)
+this object transforms simply under the spectral transformation of the left sector:
+˜r(u) → ˜r(u + γ).
+(3.29)
+In the following, intermediate calculations with R(u) are simpler, but using ˜R(u) leads to
+some simpler results. The translation between them is easy since they are related by an
+overall central normalization factor.
+3.4
+Drinfeľd’s relations II.
+We still have not verified Drinfeľd’s relation (3.1). It is slightly more subtle because of large
+spectral parameter expansion that we are using. In particular, we calculated the asymptotic
+expansion of R(u) as in (3.5). If we take equation (3.1) literally, the right-hand side as well
+as the coproduct on the left-hand side would be u-independent, so the term of order u0
+would immediately tell us that the coproduct and its opposite agree which does not make
+sense. In order to make sense of (3.1) order by order in u, we need to introduce the spectral
+parameter u also in the coproduct, analogously to (2.7). Therefore, we will consider the
+relation in the form
+R(u)Su(∆(x))R(u)−1
+!= Su(∆op(x))
+(3.30)
+where Su is the spectral shift by γ = u in the first factor. With no loss of generality we do
+not need to do any spectral shift in the second factor, because of the intertwining property
+∆(Sγ(x)) = Sγ( ¯Sγ(∆(x))).
+(3.31)
+Returning to (3.30), let us see what these equations explicitly imply for fields of lower
+dimension. The simplest choice is taking x = U1(z). For this choice, both coproduct and
+the opposite coproduct agree,
+∆(U1) = U1 + ¯U1 = ∆op(U1)
+(3.32)
+and
+Su(∆(U1)) = U1 + ¯U1 + uN = Su(∆op(U1))
+(3.33)
+so (3.30) is in this case equivalent to commutativity of R(u) with the total spin 1 generator
+U1 + ¯U1. The first non-trivial choice is x = U2(z). Here we have
+∆(U2) = U2 + ¯U2 + (U1 ¯U1) + α0N∂ ¯U1
+(3.34)
+– 17 –
+
+∆op(U2) = U2 + ¯U2 + (U1 ¯U1) + α0 ¯N∂U1
+(3.35)
+and therefore
+Su(∆(U2)) = u2
+2 N(N − 1) + u(N − 1)U1 + uN ¯U1 + U2 + ¯U2 + (U1 ¯U1) + α0N∂ ¯U1
+Su(∆op(U2)) = u2
+2 N(N − 1) + u(N − 1)U1 + uN ¯U1 + U2 + ¯U2 + (U1 ¯U1) + α0 ¯N∂U1.
+(3.36)
+The identity (3.30) with x = U2(z) is therefore equivalent to
+R(u)
+�
+−uU1 + U2 + ¯U2 + (U1 ¯U1) + α0N∂ ¯U1
+�
+=
+=
+�
+−uU1 + U2 + ¯U2 + (U1 ¯U1) + α0 ¯N∂U1
+�
+R(u).
+(3.37)
+Using explicit expressions for r(j) given in appendix B.3, we can verify this identity is indeed
+satisfied (to the order in large u expansion that we considered). We can similarly verify for
+x = U3(z), . . . that to order that we calculated R(u) Drinfeľd’s relation (3.1) is satisfied.
+4
+ILW Hamiltonians
+We will now use the universal R-matrix to construct commuting Hamiltonians of ILW
+hierarchy [25, 41]. Having constructed an R-matrix satisfying the Yang-Baxter equation
+with spectral parameter, we can use the standard technology from quantum integrability
+to construct an infinite collection of commuting Hamiltonians [34, 35].
+For R-matrices
+acting in finite dimensional vector spaces it is enough to take a trace of R-matrix over one
+of the factors (usually called the auxiliary space) that it is acting on. We are left with
+one-parametric family (parametrized by spectral parameter u) of operators that act on the
+remaining factor. These operators commute for different values of u as follows from the
+Yang-Baxter equation and therefore we obtain a collection of commuting Hamiltonians.
+In our setup there is a slight twist to this procedure, because the vector spaces involved
+are infinite dimensional. For this reason the trace is not well-defined and the construction of
+the commuting Hamiltonians needs to be modified. One possibility explored in [38, 39] is to
+consider the vacuum-to-vacuum matrix element instead of the trace. In general it is not true
+that taking an arbitrary matrix element would lead to commuting quantities, but for our
+choice of R-matrix and the vacuum matrix element this is true. The resulting Hamiltonians,
+although non-local from CFT point of view, are related to Yangian generators of the algebra
+[26, 39] and have spectrum that is easy to describe. In particular, their spectrum can be
+written in terms of combinatorics of partitions or plane partitions (3d Young diagrams).
+There is another possibility of producing commuting Hamiltonians: instead of taking
+the trace of R over the auxiliary space, we can take the regularized trace [25, 41], schemat-
+ically of the form
+Tr
+�
+q
+¯L0R(u)
+�
+.
+(4.1)
+Here ¯L0 is the ‘energy’ acting on the auxiliary space and |q| < 1 is a complex regulator.
+In the q → 1 limit we expect to reduce to the usual (ill-defined) trace.
+On the other
+– 18 –
+
+hand, in the limit q → 0 (after appropriate rescaling) only the vacuum-to-vacuum matrix
+element contributes and we should obtain the Yangian Hamiltonians. It turns out that
+the Hamiltonians constructed using this regularized trace mutually commute for arbitrary
+fixed value of q (and for varying value of spectral parameter) and can be identified with
+Hamiltonians of quantum ILW hierarchy [25]. From the CFT point of view we are studying
+the situation where the right part of R-matrix is inserted along a circle on a torus whose
+shape (complex structure) is controlled by q (see Figure 1).
+As we will see later, the
+parameter q enters the Bethe ansatz equations in the same way as the twist parameter in
+quantum spin chains, i.e. controls the twisting that the we can do when we are closing
+an open spin chain into a closed one. For general q the Hamiltonians that we obtain are
+non-local, but they become local in the (singular) q → 1 limit and as we will see later they
+will agree with the local Hamiltonians considered in [8, 14, 22].
+We will now find explicit expressions for first few ILW Hamiltonians. As usual, the
+expressions simplify when we take the logarithm of the generating function of Hamiltonians.
+In this way, although non-local, the non-locality takes a specific form. From now on we will
+restrict to ¯N = 1 so
+¯U1 ≡ ¯J,
+¯Uj = 0, j ≥ 2
+(4.2)
+and the vacuum representation on the right, i.e. the lowest weight vector in the right factor
+will satisfy
+¯Jm |0⟩ = 0,
+m ≥ 0.
+(4.3)
+Different choice of lowest weight vector (in particular ¯J0 eigenvalue) can be related to our
+calculation by shift of the spectral parameter.
+For any operator O we will define the normalized expectation value (regularized trace
+over the auxiliary space) by
+⟨O⟩q ≡ Trq ¯T0O
+Trq ¯T0 .
+(4.4)
+Note that since the zero mode of the stress-energy tensor ¯L0 on the plane and on the
+cylinder ¯T0 differ only by a constant, such a constant would cancel between the numerator
+and the denominator so we can equivalently replace ¯T0 by ¯L0. Since we are restricting to
+¯N = 1, the Fock space over which we are taking the trace has states labeled by Young
+diagrams and ¯L0 simply counts the number of boxes in the corresponding Young diagram.
+Therefore, the expectation value can also be written as
+⟨O⟩q =
+�
+λ q|λ| ⟨¯λ| O |¯λ⟩
+�
+λ q|λ|
+.
+(4.5)
+The sum is over all Young diagrams λ and |λ| denotes the number of boxes. The Hilbert
+space vectors |¯λ⟩ form a basis of the barred (auxiliary) Hilbert space. By definition, the
+expectation value of any constant (or of any operator that acts proportional to the identity
+operator in the barred Hilbert space) is the operator itself. For more interesting example,
+let us consider the expectation value of ¯L0:
+⟨¯L0⟩q =
+�
+λ |λ|q|λ|
+�
+λ q|λ|
+= q∂q log
+�
+λ
+q|λ| = q∂q log
+� ∞
+�
+k=1
+1
+1 − qk
+�
+– 19 –
+
+=
+∞
+�
+k=1
+kqk
+1 − qk = 1 − E2(q)
+24
+.
+(4.6)
+where E2(q) is the second holomorphic Eisenstein series (weight 2 quasi-modular form), see
+appendix C. The result is simpler when expressed in terms of cylinder zero mode ¯T0:
+⟨ ¯T0⟩q = ⟨¯L0 − 1
+24⟩q = −E2(q)
+24
+.
+(4.7)
+We are now ready to evaluate the first ILW Hamiltonians: we define
+Hq(u) ≡ ⟨R(u)⟩q
+(4.8)
+as well as the large u expansion of its logarithm
+log Hq(u) ≡
+∞
+�
+j=1
+(log Hq)j
+uj
+.
+(4.9)
+Since R(u) is itself an exponential of integral of local fields, we are taking here a loga-
+rithm of an expectation value of an exponential, i.e. the quantities (log Hq)j will be (non-
+commutative) connected expectation values of r(j). For the first few of these quantities we
+find
+(log Hq)1 = ⟨r(1)⟩
+(4.10)
+(log Hq)2 = ⟨r(2)⟩ + 1
+2
+�
+⟨r(1)2⟩ − ⟨r(1)⟩2�
+(4.11)
+(log Hq)3 = ⟨r(3)⟩ + 1
+2
+�
+⟨r(1)r(2)⟩ − ⟨r(1)⟩⟨r(2)⟩ + ⟨r(2)r(1)⟩ − ⟨r(2)⟩⟨r(1)⟩
+�
++
+�1
+6⟨r(1)3⟩ − 1
+4⟨r(1)2⟩⟨r(1)⟩ − 1
+4⟨r(1)⟩⟨r(1)2⟩ + 1
+3⟨r(1)⟩3
+�
+(4.12)
+(log Hq)4 = ⟨r(4)⟩ + 1
+2
+�
+⟨r(1)r(3)⟩ − ⟨r(1)⟩⟨r(3)⟩ + ⟨r(2)2⟩ − ⟨r(2)⟩2 + ⟨r(3)r(1)⟩ − ⟨r(3)⟩⟨r(1)⟩
+�
++
+�1
+6⟨r(1)2r(2)⟩ − 1
+4⟨r(1)2⟩⟨r(2)⟩ − 1
+4⟨r(1)⟩⟨r(1)r(2)⟩ + 1
+3⟨r(1)⟩2⟨r(2)⟩
+�
++
+�1
+6⟨r(1)r(2)r(1)⟩ − 1
+4⟨r(1)r(2)⟩⟨r(1)⟩ − 1
+4⟨r(1)⟩⟨r(2)r(1)⟩ + 1
+3⟨r(1)⟩⟨r(2)⟩⟨r(1)⟩
+�
++
+�1
+6⟨r(2)r(1)2⟩ − 1
+4⟨r(2)r(1)⟩⟨r(1)⟩ − 1
+4⟨r(2)⟩⟨r(1)2⟩ + 1
+3⟨r(2)⟩⟨r(1)⟩2
+�
+(4.13)
++
+� 1
+24⟨r(1)4⟩ − 1
+12⟨r(1)3⟩⟨r(1)⟩ − 1
+12⟨r(1)⟩⟨r(1)3⟩ − 1
+8⟨r(1)2⟩2
++ 1
+6⟨r(1)⟩2⟨r(1)2⟩ + 1
+6⟨r(1)⟩⟨r(1)2⟩⟨r(1)⟩ + 1
+6⟨r(1)2⟩⟨r(1)⟩2 − 1
+4⟨r(1)⟩4�
+where we write expectation values ⟨. . .⟩q without the subscript q when this is clear from
+the context. As already mentioned, taking these non-commutative connected expectation
+values will make the non-localities in (log H)j milder in the sense that will become clearer
+as we proceed.
+– 20 –
+
+First ILW Hamiltonian
+We can now turn to the first Hamiltonian (log H)1. All we
+need to do is to take the expectation value of (3.8),
+(log Hq)1 = ⟨−α0T0 − α0N ¯T0 + α0(U1 ¯U1)0⟩q
+(4.14)
+= −α0T0 − α0N⟨ ¯T0⟩q + α0⟨(U1 ¯U1)0⟩q.
+(4.15)
+In (4.7) we already calculated the expectation value of ¯T0 so it only remains to evaluate the
+expectation value of the last term, but this clearly vanishes (because ¯J0 acts as zero and
+non-zero mode operators have vanishing expectation values). We therefore find
+(log Hq)1 = −α0T0 + α0NE2
+24
+.
+(4.16)
+We see that the first Hamiltonian is up to a constant equal to L0, i.e. the standard (holo-
+morphic part of the) Hamiltonian associated to radial quantization in CFT, independently
+of q. Only the higher Hamiltonians will have non-trivial q-dependence, the Hamiltonian
+L0 is shared by the BLZ, Yangian or the general ILW family of Hamiltonians. The typical
+representation spaces are infinite dimensional, but since the higher commuting quantities
+commute with L0, the diagonalization of these is reduced to (finite dimensional) eigensub-
+spaces of L0 and therefore the diagonalization is effectively a finite dimensional problem.
+Second ILW Hamiltonian
+Let us now turn to the second ILW Hamiltonian.
+From
+(4.11) we need to evaluate ⟨r(2)⟩ as well as the connected expectation value of r(1)2. We
+have
+⟨r(2)⟩q =
+�α0 ¯N
+2
+φ3,0 − α0(T ¯U1)0 + α0(U1 ¯T)0 − α0N
+2
+¯φ3,0
+�
+q
+= α0
+2 φ3,0 + α0U1,0⟨ ¯T0⟩q − α0N
+6
+⟨( ¯J( ¯J ¯J))0⟩q
+(4.17)
+= α0
+2 φ3,0 − α0E2
+24 U1,0
+where we used the fact that the expectation values of objects involving odd powers of ¯J
+vanish by Z2 symmetry (this would not be the case if we did not restrict to auxiliary
+representation with ¯J0 ∼ 0). For the connected expectation value of r(1)2 we have
+⟨r(1)2⟩q − ⟨r(1)⟩2
+q =
+��
+−α0T0 − α0N ¯T0 + α0(U1 ¯U1)0
+�2�
+q −
+�
+−α0T0 − α0N ¯T0 + α0(U1 ¯U1)0
+�2
+q
+= +α2
+0N2⟨ ¯T 2
+0 ⟩c − α2
+0⟨T0(U1 ¯U1)0⟩c − α2
+0⟨(U1 ¯U1)0T0⟩c
+(4.18)
+− α2
+0N⟨ ¯T0(U1 ¯U1)0⟩c − α2
+0N⟨(U1 ¯U1)0 ¯T0⟩c + α2
+0⟨(U1 ¯U1)2
+0⟩c
+Here we introduced a notation for connected expectation values,
+⟨AB⟩c ≡ ⟨AB⟩q − ⟨A⟩q⟨B⟩q
+(4.19)
+Using the calculations and formulas for expectation values in appendix C, we can simplify
+this to
+⟨r(1)2⟩q − ⟨r(1)⟩2
+q = α2
+0N2 E4 − E2
+2
+288
++ α2
+0
+��
+m>0
+m1 + qm
+1 − qm U1,−mU1,m + N
+�
+m>0
+m2qm
+1 − qm
+�
+(4.20)
+– 21 –
+
+Notice that most terms disappeared when we take the connected expectation values. Adding
+this result together with the expression for the expectation value of r(2), we finally find
+(log Hq)2 = α0
+2
+�
+U3 − (U1U2) + 1
+3(U1(U1U1))
+�
+0
++ α2
+0
+2
+�
+m>0
+m1 + qm
+1 − qm U1,−mU1,m
+− α0E2
+24 U1,0 + α2
+0N2 E4 − E2
+2
+576
++ α2
+0N
+2
+�
+m>0
+m2qm
+1 − qm
+(4.21)
+On the first line we see the first non-trivial ILW Hamiltonian. It is a sum of two terms,
+first being local while the second one involving
+�
+m>0
+m1 + qm
+1 − qm U1,−mU1,m ≡
+�
+m>0
+(dm + d−m)U1,−mU1,m
+(4.22)
+which cannot be written as a zero mode of a local operator. Here we use the modified
+derivative
+dm ≡
+m
+1 − qm .
+(4.23)
+The non-locality of the product of two U1(z) fields is controlled by q-dependent
+(dm + d−m) = m1 + qm
+1 − qm = m coth
+�m log q
+2
+�
+(4.24)
+which at fixed q is an even function of m. In the limit q → 1 we have
+m1 + qm
+1 − qm ∼
+2
+1 − q − 1 + m2 − 1
+6
+(1 − q)1 + O((1 − q)2).
+(4.25)
+We see that every coefficient of (1−q)j is a polynomial in m2, so all the coefficients in 1−q
+expansion of (log Hq)2 are zero modes of local operators. On the other hand, in the limit
+q → 0 we have instead
+m1 + qm
+1 − qm → |m|
+(4.26)
+so in this limit (log Hq)2 cannot be written as a zero mode of a local operator (one would
+need to use the Hilbert transform to produce the absolute value of the Fourier mode |m|).
+We find a non-locality typical of Benjamin-Ono hierarchy which also appears in the affine
+Yangian context [27, 50].
+In the limit q → ∞ we find the same absolute value of the
+mode number (which corresponds to charge conjugate Yangian Hamiltonians). It is very
+interesting that the parameter q which in our construction appears geometrically as a shape
+(complex structure) of the auxiliary torus naturally controls the non-locality of the higher
+Hamiltonians and in particular interpolates between the local limit at q = 1 (which is
+expected to be related to BLZ-like integrals of motion) and non-local limit of the Benjamin-
+Ono / Yangian type (at q = 0 and q → ∞). For q equal to a root of unity we get local
+twisted Hamiltonians as will be illustrated later. For other values of q, we get generically
+the intermediate long wave Hamiltonians. There exists also an elliptic generalization of this
+type of non-local interaction terms, see for instance [31].
+– 22 –
+
+In a similar manner, we can find explicit expressions for higher order ILW Hamiltonians.
+Since the calculations get very long very quickly, we only determine (log Hq)3, (log Hq)4
+and (log Hq)5.
+Explicit expressions for first two of these as well as some details of the
+calculation are given in the appendix C.
+Spectral translation
+It is useful to verify how do the ILW Hamiltonians that we found
+transform under the shift of the spectral parameter. The transformation of (log H)j under
+(3.25) is inherited from that of R-matrix (3.26),
+(log Hq)j →
+j−1
+�
+k=0
+�j − 1
+k
+�
+(−γ)k(log Hq)j−k + (−γ)j
+j
+α0U1,0 − (−γ)j+1
+j(j + 1) Nα0.
+(4.27)
+More explicitly, it is easy to check using the explicit forms of the Hamiltonians that
+(log Hq)1 → (log Hq)1 − γα0U1 − γ2
+2 Nα0
+(4.28)
+(log Hq)2 → (log Hq)2 − γ(log Hq)1 + γ2
+2 α0U1,0 + γ3
+6 Nα0
+(4.29)
+(log Hq)3 → (log Hq)3 − 2γ(log Hq)2 + γ2(log Hq)1 − γ3
+3 α0U1,0 − γ4
+12α0N
+(4.30)
+(log Hq)4 → (log Hq)4 − 3γ(log Hq)3 + 3γ2(log Hq)2 − γ3(log Hq)1
+(4.31)
++ γ4
+4 α0U1,0 + γ5
+20α0N
+(4.32)
+where we used the transformation properties
+U1,0 → U1,0 + γN
+(4.33)
+Tm → Tm + γU1,m + γ2 N
+2 δm,0
+(4.34)
+φ3,m → φ3,m + 2γTm + γ2U1,m + γ3 N
+3 δm,0
+(4.35)
+φ4,0 → φ4,0 − 3γφ3,0 − 3γ2T0 − γ3U1,0 − γ4 N
+4
+(4.36)
+φ5,0 → φ5,0 − 4γφ4,0 + 6γ2φ3,0 + 4γ3T0 + γ4U1,0 + γ5 N
+5 .
+(4.37)
+5
+Spectrum and Bethe equations
+After having constructed the ILW Hamiltonians, we can now study their spectra. We will
+proceed in few steps. First of all, since we are normalizing the R-matrices as in (2.9) and
+(3.5), the lowest weight vector (vacuum) eigenvalue of R on the cylinder is non-trivial,
+capturing the higher spin Casimir charges of the zero modes of the local fields, so we first
+determine these. Afterwards, we determine the spectrum of operators obtained by taking
+the vacuum matrix element on the left or on the right side. The resulting operators are
+Yangian Hamiltonians, so they can be diagonalized explicitly in terms of combinatorics of
+partitions (or plane partitions). Their spectrum will give us on one hand the ground state
+eigenvalue of ILW Hamiltonians and on the other hand the q → 0 limit of their spectrum.
+– 23 –
+
+Finally, we diagonalize the general q-dependent ILW Hamiltonians that we determined
+explicitly in the previous section. We will parametrize their eigenvalues in terms of solutions
+of Bethe ansatz equations of Litvinov [25] and compare the result with Yangian version of a
+formula derived by Feigin-Jimbo-Miwa-Mukhin in the context of quantum toroidal algebra
+[40, 51].
+5.1
+Normalization and higher Casimir charges
+Using the formula (A.22), it is easy to evaluate the vacuum expectation values of r(j). The
+first few values are
+⟨a| r(1) |a⟩ = α2
+0
+12 − α2
+0a2
+2
+(5.1)
+⟨a| r(2) |a⟩ = −α3
+0a
+12 + α3
+0a3
+6
+(5.2)
+⟨a| r(3) |a⟩ = −α4
+0(3 + α2
+0)
+360
++ α4
+0a2
+12
+− α4
+0a4
+12
+(5.3)
+⟨a| r(4) |a⟩ = α5
+0(3 + α2
+0)a
+120
+− α5
+0a3
+12
++ α5
+0a5
+20
+(5.4)
+⟨a| r(5) |a⟩ = α6
+0(5 + 5α2
+0 + α4
+0)
+1260
+− α6
+0(3 + α2
+0)a2
+60
++ α6
+0a4
+12
+− α6
+0a6
+30
+(5.5)
+where |a⟩ is the lowest weight vector with respect to J− with zero mode eigenvalue α0a (so
+eigenvalue a of J1, see (2.5)). The a-dependence is completely determined from the spectral
+translation (3.29) so we may focus on the case of a = 0. In this case, the coefficients of
+even powers of u vanish and for the remaining ones we have
+⟨0| r(2l−1) |0⟩ =
+l−1
+�
+k=0
+B2l × (2l − k − 2)!α4l−2k−2
+0
+2l × k!(2l − 2k − 1)!
+.
+(5.6)
+This means that the vacuum eigenvalue of r(u) has an asymptotic expansion
+⟨0| r(u) |0⟩ =
+∞
+�
+l=1
+l−1
+�
+k=0
+B2l × (2l − k − 2)!α4l−2k−2
+0
+2l × k!(2l − 2k − 1)!
+1
+(α0u)2l−1
+(5.7)
+The internal sum can be evaluated if we introduce the Nekrasov-like parameters [26, 27]
+ϵ3 = α0,
+ϵ1 + ϵ2 + ϵ3 = 0,
+ϵ1ϵ2 = −1.
+(5.8)
+We have
+l−1
+�
+k=0
+(2l − 1)(2l − k − 2)!α2l−1−2k
+0
+k!(2l − 2k − 1)!
+= −ϵ2l−1
+1
+− ϵ2l−1
+2
+(5.9)
+so as asymptotic series at large u,
+⟨0| r(u) |0⟩ = −
+∞
+�
+l=1
+B2l
+2l(2l − 1)
+��ϵ1
+u
+�2l−1
++
+�ϵ2
+u
+�2l−1�
+.
+(5.10)
+– 24 –
+
+This asympotic expansion captures all the higher Casimir charges of the vacuum state. To
+proceed, it is useful to consider ˜r defined in (3.28) which includes zero mode of spin 0 and
+spin 1 operators and transforms nicely under spectral translation. We have
+⟨0| ˜r(u) |0⟩ = −α0(u log u − u) −
+∞
+�
+l=1
+B2l
+2l(2l − 1)
+��ϵ1
+u
+�2l−1
++
+�ϵ2
+u
+�2l−1�
+.
+(5.11)
+This is very reminiscent of the asymptotic expansion of Γ function, the Stirling formula
+log Γ(z) ∼
+�
+z − 1
+2
+�
+log z − z + 1
+2 log(2π) +
+∞
+�
+j=1
+B2j
+2j(2j − 1)z2j−1
+(5.12)
+so
+⟨0| ˜r(u) |0⟩ ∼ − log Γ
+� u
+ϵ1
+�
+− log Γ
+� u
+ϵ2
+�
++
+� u
+ϵ1
+�
+log 1
+ϵ1
++
+� u
+ϵ2
+�
+log 1
+ϵ2
+− 1
+2 log u
+ϵ1
+− 1
+2 log u
+ϵ2
++ log(2π).
+(5.13)
+Since we calculated the R-matrix perturbatively in large u expansion and the asymptotic
+series for gamma function at infinity is not convergent (due to infinite sequence of poles at
+negative integers), strictly speaking the normalization of R that we used is not well-defined.
+But this is easy to fix: we can just choose different normalization of R, for example the non-
+perturbative completion in terms of gamma functions as in (5.13) or alternatively we can
+normalize R such that the vacuum expectation value is unity, as was done in [38, 39]. For
+our purposes these issues are not relevant since they affect only the overall normalization
+factor, the ratios of matrix elements of R between any two states (of definite L0 level) are
+given by rational functions of the spectral parameter so there is no issue of convergence
+here (see the next paragraph or [39] where some of these matrix elements are evaluated).
+5.2
+Spectrum of ILW Hamiltonians at q → 0
+In the limit q → 0 the ILW Hamiltonians reduce to Yangian Hamiltonians [39, 41]. The
+spectrum of these has nice combinatorial description in terms of Young diagrams or their
+generalizations (N-tuples of these or plane partitions with various asymptotics). At lower
+levels, the eigenvalues can be calculated as exact functions of the spectral parameter u
+directly from the definition of the R-matrix. Let us illustrate this on an example. The
+elementary R-matrix at level 1 acts as
+R(u)J−1 |a, ¯a⟩ =
+u + a − ¯a
+u + a − ¯a + ϵ3
+ECas(u)J−1 |a, ¯a⟩ +
+ϵ3
+u + a − ¯a + ϵ3
+ECas(u) ¯J−1 |a, ¯a⟩
+(5.14)
+R(u) ¯J−1 |a, ¯a⟩ =
+ϵ3
+u + a − ¯a + ϵ3
+ECas(u)J−1 |a, ¯a⟩ +
+u + a − ¯a
+u + a − ¯a + ϵ3
+ECas(u) ¯J−1 |a, ¯a⟩
+(5.15)
+as immediately follows from (2.8) [39]. Here a is the lowest weight eigenvalue of J0 and
+¯a is the lowest weight eigenvalue of ¯J0. ECas(u) is the eigenvalue of R(u) acting on the
+– 25 –
+
+lowest weight state |a, ¯a⟩ (the normalization factor). In the limit q → 0 instead of taking
+the normalized trace over the right Hilbert space we simply take the vacuum expectation
+value on the right. Therefore, on level 1 in the case of N = 1 = ¯N (and ¯a = 0) we have
+Hq=0(u)J−1 |a⟩ =
+u + a
+u + a + ϵ3
+ECas(u)J−1 |a⟩ .
+(5.16)
+A similar calculation at level 2 shows that the eigenvalues of Hq=0(u) at level 2 are
+(u + a)(u + a − ϵ1)
+(u + a + ϵ3)(u + a − ϵ1 + ϵ3)ECas(u),
+(u + a)(u + a − ϵ2)
+(u + a + ϵ3)(u + a − ϵ2 + ϵ3)ECas(u).
+(5.17)
+This calculation can be performed also for general values of integers N and ¯N. At level 1
+we have N eigenvalues
+ECas(u) ×
+¯
+N
+�
+l=1
+u + ak − ¯al
+u + ak − ¯al + ϵ3
+,
+k = 1, . . . , N.
+(5.18)
+(corresponding to a single box inserted at u = −ak, k = 1, . . . N) and similarly at level 2
+we have N eigenvalues
+ECas(u) ×
+¯
+N
+�
+l=1
+(u + ak − ¯al)(u + ak − ¯al − ϵ1)
+(u + ak − ¯al + ϵ3)(u + ak − ¯al − ϵ1 + ϵ3),
+k = 1, . . . N,
+(5.19)
+N eigenvalues
+ECas(u) ×
+¯
+N
+�
+l=1
+(u + ak − ¯al)(u + ak − ¯al − ϵ2)
+(u + ak − ¯al + ϵ3)(u + ak − ¯al − ϵ2 + ϵ3),
+k = 1, . . . N,
+(5.20)
+and N(N − 1)/2 eigenvalues
+ECas(u) ×
+¯
+N
+�
+l=1
+(u + ak1 − ¯al)(u + ak2 − ¯al)
+(u + ak1 − ¯al + ϵ3)(u + ak2 − ¯al + ϵ3),
+1 ≤ k1 < k2 ≤ N.
+(5.21)
+The general form of the eigenvalues should be clear: a general state in the Fock space
+of N free bosons is labeled by N-tuple of Young diagrams λ(k), k = 1, . . . , N. Each box of
+each Young diagram has an associated Bethe root
+x = −ak + ϵ1c1(□) + ϵ2c2(□) ≡ −ak + ϵ□
+(5.22)
+where cj(□) are the cartesian coordinates of the box of the Young diagram λ(k), starting
+with the first box at coordinates (0, 0).5
+The eigenvalues of Hq=0(u) acting on a state
+5A better and more symmetric way of writing this would be to consider the Young diagram lying in 1−2
+plane of three-dimensional space and write the corresponding Bethe root as −ak+ϵ1c1(□)+ϵ2c2(□)+ϵ3c3(□).
+Here c3(□) is the same for all boxes of the Young diagram (since it lies in 1 − 2 plane) and it is natural to
+choose the coordinates of the first box to be either (0, 0, 0) or (1, 1, 1) which does not affect the associated
+Bethe roots due to the identity ϵ1 + ϵ2 + ϵ3 = 0.
+– 26 –
+
+|λ(1), . . . , λ(N)⟩ which has associated Bethe roots xℓ, ℓ = 1, . . . , M where M = |λ(1)| + . . . +
+|λ(N)| is the total number of boxes is
+Hq=0(u) |λ(1), . . . , λ(N)⟩ = ECas(u)
+M
+�
+ℓ=1
+¯
+N
+�
+k=1
+u − xℓ − ¯ak
+u − xℓ − ¯ak + ϵ3
+|λ(1), . . . , λ(N)⟩ .
+(5.23)
+In the previous example at level 2, we had N states with Young diagram
+in the k-th
+layer, k = 1, . . . , N, another N states with Young diagram
+in the k-th layer, k = 1, . . . , N
+and finally N(N−1)/2 states with two Young diagrams
+, one in the k1-th layer and another
+in the k2-th layer.
+For later purposes, it will be convenient to write the spectrum of (log Hq=0)j in terms
+of symmetric polynomials in Bethe roots (specializing again to ¯N = 1 and ¯a = 0). In order
+to do that, we just need to take the logarithm of (5.23) and extract the corresponding
+coefficients. We find
+(log Hq=0) → log ECas(u) +
+M
+�
+ℓ=1
+log
+�
+u − xℓ
+u − xℓ + ϵ3
+�
+(5.24)
+≃ log ECas(u) +
+∞
+�
+j=1
+1
+juj
+�j−1
+�
+k=0
+(−1)j−k
+�j
+k
+�
+pkϵj−k
+3
+�
+(5.25)
+where
+pj =
+M
+�
+ℓ=1
+xj
+ℓ
+(5.26)
+are the Newton power sum polynomials of the Bethe roots and p0 ≡ M = �
+j |λ(j)|, the
+total number of Bethe roots (which is the level of the corresponding state). Explicitly,
+(log Hq=0)1 → (log Hq=0)1,hw − ϵ3p0
+(5.27)
+(log Hq=0)2 → (log Hq=0)2,hw − ϵ3p1 + ϵ2
+3
+2 p0
+(5.28)
+(log Hq=0)3 → (log Hq=0)3,hw − ϵ3p2 + ϵ2
+3p1 − ϵ3
+3
+3 p0
+(5.29)
+(log Hq=0)4 → (log Hq=0)4,hw − ϵ3p3 + 3
+2ϵ2
+3p2 − ϵ3
+3p1 + ϵ4
+3
+4 p0
+(5.30)
+In particular, the Hamiltonians extracted from the logarithm of Hq=0 are linear functions
+of the Newton sums pk with coefficients that are independent of N and of lowest weight
+charges. The dependence on N and on the lowest weight charges comes both from the
+lowest weight state contribution as well as from the explicit dependence of Bethe roots on
+N and on the lowest weight charges. The linearity of these charges in pj is special to q = 0
+limit of the ILW Hamiltonians and will not survive the deformation to q → 0.
+With the choice of normalization of R that we are using here, the contribution from
+the Casimir charges can be obtained from (5.7) and we find
+(log Hq=0)1,hw = α0
+�
+u2 − u2
+1
+2 + N
+12
+�
+(5.31)
+– 27 –
+
+(log Hq=0)2,hw = α0
+2
+�
+u3 − u1u2 + u3
+1
+3 − u1
+6
+�
+(5.32)
+(log Hq=0)3,hw = α0
+3
+�
+u4 − u1u3 − u2
+2
+2 + u2
+1u2 − u4
+1
+4 − u2
+2 + u2
+1
+4 − N(3 + α2
+0)
+120
+�
+(5.33)
+(log Hq=0)4,hw = α0
+4
+�
+u5 − u1u4 − u2u3 + u2
+1u3 + u1u2
+2 − u3
+1u2 + u5
+1
+5
+− u3 + u1u2 − u3
+1
+3 + (3 + α2
+0)u1
+30
+�
+.
+(5.34)
+5.3
+Ground state eigenvalue of ILW Hamiltonians
+We can next use the knowledge of the spectrum of Yangian Hamiltonians to determine
+the lowest weight state eigenvalue of Hq for q ̸= 0.
+Similarly to the discussion in the
+previous section, if we take the vacuum-to-vacuum matrix element on the left and allow for
+an arbitrary ¯N = 1 state on the right, we find eigenvalues
+¯H¯q=0(u) |¯λ⟩ = ECas(u)
+�
+□∈λ
+N
+�
+j=1
+u + aj − ¯a − ϵ□
+u + aj − ¯a − ϵ□ + ϵ3
+|¯λ⟩
+(5.35)
+were λ runs over all Young diagrams (states of the right Fock space). Therefore, the lowest
+weight state eigenvalue of Hq is
+⟨{aj}| Hq(u) |{aj}⟩ = ECas(u)
+�
+λ q|λ| ×
+�
+λ
+q|λ| �
+□∈λ
+N
+�
+j=1
+u + aj − ϵ□
+u + aj − ϵ□ + ϵ3
+(5.36)
+where we put ¯a = 0. Writing this in the form
+⟨{aj}| log Hq(u) |{aj}⟩ = log ECas(u) + log
+�
+exp
+�
+□∈λ
+N
+�
+j=1
+log
+u + aj − ϵ□
+u + aj − ϵ□ + ϵ3
+�
+(5.37)
+The second term on the right-hand side can be Taylor expanded at large u as
+log
+�
+exp
+∞
+�
+k=1
+1
+kuk
+k
+�
+l=1
+k−l
+�
+m=0
+(−1)l+mk!ϵl
+3
+��N
+j=1 am
+j
+� ��
+□∈λ ϵk−l−m
+□
+�
+l!m!(k − l − m)!
+�
+(5.38)
+This is of the form of the logarithm of the exponential of the expectation value of an
+expression bilinear in power sums of Bethe roots and power sums of zero modes aj. As
+such, its large u expansion coefficients are determined in terms of connected expectation
+values of these Newton polynomials. Denoting the sum of k-th powers of Bethe roots by
+Ok =
+�
+□∈λ
+ϵk
+□,
+(5.39)
+we find the large u expansion of the vacuum eigenvalue of ILW Hamiltonians to be
+log ECas(u) + log
+�
+exp
+∞
+�
+k=1
+1
+kuk
+k
+�
+l=1
+k−l
+�
+m=0
+(−1)l+mk!ϵl
+3
+��N
+j=1 am
+j
+�
+l!m!(k − l − m)!
+Ok−l−m
+�
+.
+(5.40)
+– 28 –
+
+For first few Hamiltonians, this is explicitly
+(log Hq)′
+1,hw = −α0N⟨O0⟩
+(5.41)
+(log Hq)′
+2,hw = −α0
+2
+�
+2N⟨O1⟩ − α0N2⟨O2
+0⟩c − (α0N + 2u1)⟨O0⟩
+�
+(5.42)
+(log Hq)′
+3,hw = −α0
+6
+�
+6N⟨O2⟩ − 6α0N2⟨O0O1⟩c + α2
+0N3⟨O3
+0⟩c
+− 6(2u1 + α0N)⟨O1⟩ + 3α0N(2u1 + α0N)⟨O2
+0⟩c
+(5.43)
++ 2(3u2
+1 − 6u2 + 3α0u1 + α2
+0N)⟨O0⟩
+�
+(log Hq)′
+4,hw = −α0
+24
+�
+24N⟨O3⟩ − 24α0N2⟨O0O2⟩c − 12α0N2⟨O2
+1⟩c
++ 12α2
+0N3⟨O2
+0O1⟩c − α3
+0N4⟨O4
+0⟩c + 36α0N(2u1 + α0N)⟨O0O1⟩c
+− 6α2
+0N2(2u1 + α0N)⟨O3
+0⟩c − 36(2u1 + α0N)⟨O2⟩
++ 24(3u2
+1 − 6u2 + 3α0u1 + α2
+0N)⟨O1⟩
+(5.44)
+− α0(12u2
+1 + 24Nu2
+1 − 48Nu2 + 36α0Nu1 + 11α2
+0N2)⟨O2
+0⟩c
+− 6(4u3
+1 − 12u1u2 + 12u3 + 6α0u2
+1 − 12α0u2 + 4α2
+0u1 + Nα3
+0)⟨O0⟩
+�
+where we did not yet add the Casimir contribution (that is the reason for putting a prime
+on the left-hand side). In order to compare with the explicit expressions for (log Hq)j, we
+need to evaluate the expectation values such as
+⟨O0⟩ =
+�
+m>0
+d−m = 1 − E2
+24
+(5.45)
+⟨O1⟩ = α0
+2
+�
+m>0
+(1 − dm + d−m)d−m = α0(1 − E2)
+48
+− α0
+2
+�
+k>0
+k2qk
+1 − qk
+(5.46)
+⟨O2
+0⟩c =
+�
+m>0
+dmd−m = E4 − E2
+2
+288
+(5.47)
+as well as higher ones whose expressions are longer so they are collected in appendix C.6.
+Using these, we finally find the prediction for eigenvalues of ILW Hamiltonian acting on the
+lowest weight state. The first two are
+(log Hq)1,hw = −α0
+�
+−u2 + u2
+1
+2 − N
+24
+�
++ α0NE2
+24
+(5.48)
+(log Hq)2,hw = α0
+2
+�
+u3 − u1u2 + 1
+3u3
+1 − u1
+12
+�
+− α0E2
+24 u1
++ α2
+0N2 E4 − E2
+2
+576
++ α2
+0N
+2
+�
+m>0
+m2qm
+1 − qm
+(5.49)
+and the expressions for (log Hq)3,hw and (log Hq)4,hw are given in appendix C.6. It is easy
+to see that both ways of calculating these expectation values lead to the same result.
+5.4
+Spectrum of (log Hq)j and Bethe ansatz
+According to conjecture of Litvinov, the ILW Hamiltonians that we have constructed can
+be diagonalized by solving the Bethe ansatz equations [25]. More concretely, to describe
+– 29 –
+
+the joint eigenspectrum at Virasoro level M, consider the following system of M algebraic
+equations for M unknown Bethe roots xj, j = 1, . . . , M
+q
+N
+�
+l=1
+xj + al − ϵ3
+xj + al
+�
+k̸=j
+(xj − xk + ϵ1)(xj − xk + ϵ2)(xj − xk + ϵ3)
+(xj − xk − ϵ1)(xj − xk − ϵ2)(xj − xk − ϵ3) = 1,
+j = 1, . . . , M.
+(5.50)
+or more concisely
+qA(xj)
+�
+k̸=j
+ϕ(xj − xk) = 1,
+j = 1, . . . , M
+(5.51)
+where
+ϕ(u) = (u + ϵ1)(u + ϵ2)(u + ϵ3)
+(u − ϵ1)(u − ϵ2)(u − ϵ3)
+(5.52)
+is the structure function of W1+∞ and
+A(u) =
+N
+�
+l=1
+xj + al − ϵ3
+xj + al
+(5.53)
+captures the information about the higher spin charges of the lowest weight vector of the
+representation (primary). 6
+From the point of view of W1+∞, these Bethe ansatz equations are very natural: the
+product over roots describes interaction between pairs of Bethe roots and is controlled by
+the unique structure constant of W1+∞ [27]. The first product encoding the information
+about higher spin charges of the lowest weight state of the representation corresponds from
+the point of view of Bethe ansatz equations to an interaction of Bethe roots with external
+fields. Each (physical) solution of BAE is associated to a eigenstate of ILW Hamiltonians.
+The solution is given by M complex Bethe roots xj, j = 1, . . . , M and eigenvalues of all
+(log Hq)k are given by symmetric polynomials in xj.
+At q = 0, we can explicitly solve these Bethe ansatz equations for any given M and
+the Bethe roots can be combinatorially associated to boxes of Young diagrams as in (5.22).
+Similar situation happens for q → ∞ but apart from these special values of q, we can solve
+the equations only numerically. In terms of these Bethe roots, the eigenvalues of the first
+ILW Hamiltonians are given by
+(log Hq)1 → −α0p0 + (log Hq)1,hw
+(5.54)
+(log Hq)2 → −α0p1 + α2
+0
+2 p0 + (log Hq)2,hw
+(5.55)
+(log Hq)3 → −α0p2 + α2
+0p1 − α0(1 + 4α2
+0)
+12
+p0 + α0E2
+12 p0 + (log Hq)3,hw
+(5.56)
+6For concreteness A(u) was written with Y00N truncation of W1+∞ in mind in terms of the corresponding
+Coulomb parametres aj (these are the zero modes of free fields in the usual free field representation of Y00N).
+For such representations and generic aj the representation spaces are N-tuples of Young diagrams stacked
+along the 3rd direction. We can replace A(u) by a product of such functions to parametrize the lowest
+weight charges of YN1N2N3 algebra (see [52] for more details) or consider more general rational function
+with value 1 at u → ∞ to get more general quasi-finite representations of the algebra [27]. Representations
+of this kind have the property that there are only finite number of states at every Virasoro level.
+– 30 –
+
+(log Hq)4 → −α0p3 + 3α2
+0
+2 p2 − α0(1 + 4α2
+0)
+4
+p1 + α2
+0(1 + 2α2
+0)
+8
+p0
+(5.57)
++ α0E2
+4
+p1 − α2
+0E2
+8
+p0 + α2
+0N E4 − E2
+2
+144
+p0 + 3α2
+0
+�
+m>0
+m2qm
+1 − qm p0 + (log Hq)4,hw
+(log Hq)5 → −α0p4 + 2α2
+0p3 − 2α3
+0p2 + α4
+0p1 − α5
+0
+5 p0 − 12α0⟨O0⟩p2 − 24α0⟨O1⟩p1
++ 24α2
+0⟨O0⟩p1 − 12α0⟨O2⟩p0 + 24α2
+0⟨O1⟩p0 − 2α0(1 + 7α2
+0)⟨O0⟩p0
+(5.58)
++ 6Nα2
+0⟨O2
+0⟩cp1 − 2α2
+0u1⟨O2
+0⟩cp0 + 8Nα2
+0⟨O0O1⟩cp0 − 7Nα3
+0⟨O2
+0⟩cp0
+− N2α3
+0(⟨O3
+0⟩ − 3⟨O2
+0⟩⟨O0⟩ + 2⟨O0⟩3) p0 + (log Hq)5,hw
+These expressions were obtained by explicit numerical diagonalization at lower levels as
+well as by using the q → 0 limit where the spectrum is known. The formulas are also
+constrained by requiring compatibility with the spectral shift. Note that although all these
+expressions are at most linear in pj, at order u−6 terms such as ⟨O2
+0⟩c p2
+0 are expected
+to appear.
+The coefficients of the symmetric polynomials in Bethe roots have explicit
+dependence on the twist parameter q via transcendental functions such as the Eisenstein
+series Ej. From the explicit form of ILW Hamiltonians we see that the coefficients of these
+transcendental functions multiply operators that are expressible in terms of lower degree
+ILW Hamiltonians. In other words, by taking a suitable triangular linear combination of
+ILW Hamiltonians we can eliminate these transcendental terms and we end up with ILW
+Hamiltonians which involve only rational functions of q and whose spectrum is given by
+symmetric polynomials in Bethe roots without any additional explicit q-dependence (all
+q-dependence comes from q-dependence of Bethe roots themselves).
+5.5
+Feigin-Jimbo-Miwa-Mukhin formula
+Based on the result of these calculations, we will now conjecture a formula for eigenvalues of
+the generating function Hq(u). The result is in the form of a rational limit of an analogous
+result proven by Feigin, Jimbo, Miwa and Mukhin in [40, 51] in the related q-deformed
+context of quantum toroidal gl(1).
+We look for the eigenvalues of the generating function Hq(u) in the form
+Hq(u) → N
+�
+λ
+q|λ|
+M
+�
+i=1
+g(u, xi)
+�
+□∈λ
+h(u, ϵ□)
+M
+�
+i=1
+�
+□∈λ
+f(u, xi, ϵ□).
+(5.59)
+where N is an overall q- and x-independent normalization prefactor. Now we can use the
+two Yangian limits that we studied previously to put restrictions on functions g and h: first
+of all, if there are no Bethe roots (i.e. the Virasoro level M = 0), we should reproduce the
+lowest weight charges that we calculated in section 5.3. In particular, we need
+ECas(u)
+�
+λ q|λ| ×
+�
+λ
+q|λ| �
+□∈λ
+N
+�
+j=1
+u + aj − ϵ□
+u + aj − ϵ□ + ϵ3
+!= N
+�
+λ
+q|λ| �
+□∈λ
+h(u, ϵ□)
+(5.60)
+from where we see that we need to identify
+N = ECas(u)
+�
+λ q|λ|
+(5.61)
+– 31 –
+
+as well as
+h(u, ϵ□) =
+N
+�
+i=1
+u + ai − ϵ□
+u + ai − ϵ□ + ϵ3
+.
+(5.62)
+The second restriction comes from the q → 0 limit. In this limit, only the vacuum state
+λ = ∅ contributes to the right-hand side of (5.59) while the left-hand side is given by (5.35).
+Bethe roots are in this case given as in (5.22) so we have
+M
+�
+i=1
+g(u, xi) !=
+M
+�
+i=1
+u − xi
+u − xi + ϵ3
+(5.63)
+or
+g(u, xi) =
+u − xi
+u − xi + ϵ3
+.
+(5.64)
+Finally, it remains to identify the function f(u, xi, ϵ□). Let us use an ansatz
+f(u, xi, ϵ□) = ϕ(u − αxi − βϵ□ − γ)
+(5.65)
+where ϕ(u) is the structure constant of W1+∞ as in (5.52). Due to restriction ϵ1+ϵ2+ϵ3 = 0,
+the Taylor series of log ϕ(u) at u → ∞ starts at order u−4, so the constants α, β and γ can
+be fixed by comparing the spectrum with that of (log Hq)4. This determines these to be
+α = 1,
+β = 1,
+γ = −α0.
+(5.66)
+Therefore, the spectrum of the generating function of ILW Hamiltonians Hq(u) is given by
+Hq(u) → ECas(u)
+�
+λ q|λ|
+M
+�
+i=1
+u − xi
+u − xi + ϵ3
+�
+λ
+q|λ| �
+□∈λ
+N
+�
+i=1
+u + ai − ϵ□
+u + ai − ϵ□ + ϵ3
+M
+�
+i=1
+�
+□∈λ
+ϕ(u−xi −ϵ□ +ϵ3).
+(5.67)
+which is a rational analogue of a formula by Feigin, Jimbo, Miwa and Mukhin. To summa-
+rize, the elements of this formula are
+• ECas(u) is the normalization factor of the R-matrix
+• ϵj are the Nekrasov-like parameters of W∞; these are determined for example by the
+rank N of WN and the central charge (i.e by the physical model such as Lee-Yang or
+Ising model)
+• the rational function ϕ(u) is the structure function of W1+∞ which governs the rep-
+resentation theory of the algebra; it can also be viewed as a scattering phase of the
+particles that are described by these Bethe ansatz equations
+• q is the complex number parametrizing which family of ILW Hamiltonians we are
+diagonalizing, different values of q correspond to different integrable structures that
+the algebra has; from R-matrix point of view it encodes the shape of the auxiliary
+torus, from spin chain point of view it is the twist parameter; it controls the degree
+of non-locality and its inversion corresponds to charge conjugation
+– 32 –
+
+• the sum over λ represents the trace over the auxiliary space (with states parametrized
+by Young diagrams since we focused on ¯N = 1)
+• ϵ□ are the Yangian Bethe roots associated to the auxiliary sector; the explicit expres-
+sions for these can be read off combinatorially from the associated Young diagram
+λ
+• ai are the parameters parametrizing the lowest weights in the quantum space (Coulomb
+parameters in the context of Nekrasov partition functions, external fields from the
+point of view of Bethe equations, eigenvalues of zero modes of scalar fields in free field
+representations of W1+∞)
+• xi are the Bethe roots which are determined by solution of Bethe equations; these
+parameters (and M which is the number of these Bethe roots) are the only parameters
+in this formula that depend on the particular eigenstate whose eigenvalues we are
+evaluating
+Since we used all the Hamiltonians up to (log Hq)4 to fix the parameters in this formula,
+we independently verified that also the spectrum of (log Hq)5 agrees with the prediction
+coming from this formula.
+In the Yangian limit a convenient generating function of higher spin charges of a state
+Λ with associated Bethe roots xj is [26, 27]
+ψΛ(u) = A(u)
+�
+j
+ϕ(u − xj).
+(5.68)
+If we use the same definition for ψΛ(u) in terms of Bethe roots even for q ̸= 0, we can
+interpret the FJMM generating function as a dressed or averaged version of ψΛ(u),
+Hq(u)
+Hq=0(u) →
+1
+�
+λ q|λ|
+�
+λ
+q|λ| �
+□∈λ
+ψΛ(u − ϵ□ + ϵ3)
+(5.69)
+=
+� �
+□∈λ
+ψΛ(u − ϵ□ + ϵ3)
+�
+q
+(5.70)
+where the average is physically the canonical Gibbs ensemble over the auxiliary space.
+6
+Local limit q → 1
+It is interesting to understand what happens in the local limit (q → 1) where the ILW
+Hamiltonians reduce to local BLZ/KP-like Hamiltonians. This limit is singular: in the
+construction of ILW Hamiltonians we used the parameter q to regularize the trace over the
+infinite dimensional auxiliary space which would otherwise not be well-defined. The local
+limit corresponds to removal of this regulator. Therefore it is not surprising that the ILW
+Hamiltonians explicitly depend on q in such a way that they become singular as q → 1.
+But this is not the only singular behavior that we encounter - clearing the denominators
+in the Bethe equations (5.50) to make them polynomial shows that in the limit q → 1 the
+– 33 –
+
+leading coefficients of the polynomials cancel, i.e. the degree of Bethe equations drops. As
+a consequence of that, some of the Bethe roots blow up in the q → 1 limit.
+As we will see, in the q → 1 limit the W∞ and Heisenberg factors of W1+∞ algebra
+decouple and the divergences of Bethe roots as q → 1 make this decoupling possible. It
+turns out that the Bethe roots that go to infinity as q → 1 are precisely those that describe
+the excitations in the Heisenberg subsector of W1+∞ while the roots that remain finite in the
+limit correspond to Bethe roots associated to W∞ subalgebra. In particular, the divergence
+of Heisenberg Bethe roots guarantees that they decouple from Bethe equations for the
+remaining W∞ Bethe roots which is an essential ingredient in the decoupling mechanism.
+From point of view of ILW Hamiltonians, for generic q we have one independent conserved
+quantity of every spin. On the other hand, if the Heisenberg and W∞ subalgebras of W1+∞
+decouple in q → 1 limit, one can expect two independent conserved quantities of every
+spin greater than or equal to 2, one conserved quantity being associated to Heisenberg
+subalgebra and the other coming from W∞. Again, it is the singular behaviour of ILW
+integrals of motion as q → 1 that makes it possible to diagonalize all of these quantities,
+although naïvely there seem to be twice as many of them as for generic q.
+q → 1 limit of (log Hq)2
+Numerical as well as analytic solution of Bethe ansatz equations
+at lower levels (for examples see the following section) shows the following pattern: first
+of all, given a solution of BAE, the individual Bethe roots are either regular in the q → 1
+limit or diverge as
+x =
+C
+1 − q + o((1 − q)−1)
+(6.1)
+where C is a universal constant, same for all Bethe roots (and independent of the specific
+solution of Bethe equations), but depending on the ϵj parameters as well as the function
+A(u) parametrizing the lowest weights. Furthermore, the number of singular Bethe roots
+exactly corresponds to the number of excitations associated to the ˆgl(1) subalgebra of W1+∞
+while the remaining Bethe roots that are finite in the limit correspond to W∞ factor of the
+algebra. Therefore, all the Bethe roots split into two groups as q → 1, those which remain
+finite (W∞ roots) and those that go to infinity (Heisenberg roots).
+This behaviour is consistent with the explicit form of ILW Hamiltonians: consider the
+first non-trivial ILW Hamiltonian
+A2 ≡ −1
+2φ3,0 − α0
+2
+�
+m>0
+m1 + qm
+1 − qm U1,−mU1,m
+(6.2)
+which is obtained from (log Hq)2 after subtracting the transcendental terms (which are in
+this case central). It has spectrum given by
+p1 − α0
+2 p0 − 1
+2u3 + 1
+2u1u2 − u3
+1
+6 + u1
+24 ≡ p1 − α0
+2 p0 + hw.
+(6.3)
+where hw denotes a constant (central) contribution that can be evaluated by acting with
+A2 on the lowest weight vector. Since φ3,0 is a q-independent operator with finite matrix
+elements in representations spaces, the only singular part in the q → 1 limit comes from
+– 34 –
+
+the second term,
+− α0
+2
+�
+m>0
+m1 + qm
+1 − qm U1,−mU1,m ∼ − α0
+1 − q
+�
+m>0
+U1,−mU1,m + O((1 − q)0).
+(6.4)
+The coefficient of (1−q)−1 term is up to normalization the (Sugawara) stress-energy tensor
+of the Heisenberg subalgebra. Inspecting the expression for eigenvalues of A2, we see that
+the only possible source of such singular behavior is from the term
+p1 =
+M
+�
+j=1
+xj.
+(6.5)
+Therefore, if M∞ out of M Bethe roots are regular while remaining M1 roots have leading
+singular behavior of the form
+C
+1 − q
+(6.6)
+with universal constant C (as we can see from the lower level solutions of the Bethe ansatz
+equations), we are lead to identify
+C
+!= −α0N = ψ0ϵ1ϵ2ϵ3.
+(6.7)
+For easier comparison, we wrote the value of C in terms of triality and scaling-covariant
+parameters [27].
+Here ψ0 is the central element of the Yangian algebra which can be
+extracted from the generating function of higher spin charges of the lowest weight state via
+A(u) = 1 + ϵ1ϵ2ϵ3
+∞
+�
+j=0
+ψj
+uj+1 .
+(6.8)
+This numerical value of C is confirmed by the results of numeric as well as analytic calcu-
+lations at lower levels.
+Since in the q → 1 limit we are diagonalizing both (log Hq)1 (which is the zero mode of
+the total W1+∞ stress-energy tensor) as well as the zero mode of the stress-energy tensor
+of ˆgl(1) (which as we saw is the dominant term in (log Hq)2 in the q → 1 limit), we see
+that among the commuting conserved quantities in the q → 1 limit we have also the zero
+mode T (∞)
+0
+of W∞. This suggests factorization of ILW conserved quantities in the local
+limit into Heisenberg conserved quantities and W∞ conserved quantities. This is further
+confirmed by studying Bethe equations (5.50): since Bethe roots associated to W∞ are
+regular in the local limit while those of ˆgl(1) are singular, we see that the contribution of
+ˆgl(1) roots decouples from the equations determining W∞ roots. This is again confirmed
+by the numerics [53]. In particular, to each W∞ solution of BAE (which has all Bethe roots
+finite) we can associate an infinite set of BAE solutions at higher levels which have the
+same collection of finite Bethe roots in the q → 1 limit. All of these states correspond to
+the same state in W∞ subsector but different state in the ˆgl(1) subsector.
+– 35 –
+
+q → 1 limit of (log Hq)3
+In order to extract the next local Hamiltonian, we need to study
+the singular behavior of (log Hq)3. Note that as we see from the lower level examples and
+numerics [53], in general the behavior of individual Bethe roots as q → 1 is not simply a
+Laurent series in integer powers of (1 − q), i.e. there are non-trivial monodromies of Bethe
+roots around q = 1 (as well as around other points in the q-plane) and we need to use
+the Puiseux series (Laurent series in fractional powers of 1 − q). But given any solution
+of Bethe equations, the examples indicate that analytic continuation around q = 1 only
+permutes Bethe roots of that solution, i.e. the power sum polynomials of Bethe roots of a
+solution have no monodromy. This is unlike the general situation around other special values
+of parameter q where even different solutions mix under the monodromy, so the analytic
+continuation around all special points in the q-plane connects different eigenstates of the
+ILW Hamiltonians, analogously to the situation in other integrable models [54]. Actually,
+as we will see in the examples in the next section, the monodromy seems to connect all
+eigenstates at given level, i.e. there is a single multivalued function of x(q) representing
+all the Bethe roots associated to physical solutions of Bethe equations at a given level.
+The fact that monodromy around q = 1 does not mix different solution is also compatible
+with q → 1 expansion of ILW Hamiltonians which after subtraction of transcendental terms
+have Laurent expansion in integer powers of (1 − q) (since the matrix elements are rational
+functions of q with poles only at roots of unity).
+Subtracting the term in (log Hq)3 proportional to E2T0 as well as the central terms, we
+see that the operator
+A3 ≡ −1
+3φ4,0 + α0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mTm + T−mU1,m)
+(6.9)
+− α2
+0(N + 2)
+12
+�
+m>0
+m2U1,−mU1,m + α2
+0N
+4
+�
+m>0
+m2(1 + qm)2
+(1 − qm)2
+U1,−mU1,m
+(6.10)
+has spectrum given by
+p2 − α0p1 + 1 + 4α2
+0
+12
+p0 + hw.
+(6.11)
+The leading singular behavior of A3 is the quadratic pole (1 − q)−2 with coefficient pro-
+portional to the �gl(1) Sugawara Hamiltonian which we already encountered in (log Hq)2.
+Therefore, in order to isolate an interesting higher Hamiltonian from (log Hq)3, we need to
+cancel this leading order term by a similar term from A2. Therefore, we consider the limit
+B3 ≡ lim
+q→1
+�
+(1 − q)A3 + α0NA2
+�
+(6.12)
+= −α0N
+2
+φ3,0 + α0
+�
+m>0
+(U1,−mTm + T−mU1,m) − α2
+0N
+2
+�
+m>0
+U1,−mU1,m
+(6.13)
+with spectrum given by
+lim
+q→1
+�
+(1 − q)p2 − (1 − q)α0p1 + α0Np1 − α2
+0N
+2
+p0
+�
++ hw.
+(6.14)
+– 36 –
+
+By construction, this operator commutes with both T (1)
+0
+and T (∞)
+0
+so in particular should
+be a sum of a zero mode of spin 3 operator in W∞ and in ˆgl(1). This is indeed the case: in
+terms of Heisenberg and W∞ modes, this operator can be written as
+B3 = −α0N
+2
+W3,0 − α0U1,0T0 + α0
+3N (U1(U1U1))0 − α2
+0N
+4
+(U1U1)0 + hw.
+(6.15)
+We used the fact that
+�
+m>0
+(U1,−mTm + T−mU1,m) = (U1T)0 − U1,0T0 + 1
+12U1,0
+(6.16)
+and introduced the unique (up to normalization) spin 3 primary field in W∞
+W3 = U3 − N − 2
+N
+(U1U2) + (N − 1)(N − 2)
+3N2
+(U1(U1U1)) − (N − 2)α0
+2
+U ′
+2
+(6.17)
++ (N − 1)(N − 2)α0
+2N
+(U ′
+1U1) + (N − 1)(N − 2)α2
+0
+12
+U ′′
+1 .
+(6.18)
+Let us Taylor expand the power sum polynomials of Bethe roots as
+p1 = p1,−1
+1 − q + p1,0 + p1,1(1 − q) + . . .
+(6.19)
+p2 =
+p2,−2
+(1 − q)2 + p2,−1
+1 − q + p2,0 + p2,1(1 − q) + . . .
+(6.20)
+The monodromy properties of Bethe roots around 1 − q as discussed above imply that the
+series expansion has only integer powers of 1 − q, i.e. is a Laurent expansion. Furthermore,
+the leading singular behaviour of power sums is determined by (6.1). Plugging this form of
+pj into (6.14), we find the expansion
+p2,−2 + α0Np1,−1
+1 − q
++ p2,−1 + α0Np1,0 + α2
+0N
+2
+M1 − α2
+0N
+2
+M∞ + hw.
+(6.21)
+where we used that p0 ≡ M = M1 + M∞ and
+p1,−1 = −α0NM1
+(6.22)
+as follows from (6.1). We see that in order for this quantity to be non-singular as q → 1,
+we need to have
+p2,−2 = −α0Np1,−1 = (−α0N)2M1.
+(6.23)
+This condition together with analogous conditions coming from higher conserved quantities
+actually imply (6.1) (with universal value of C), so we find an a posteriori reason coming
+from the representation theory for validity of (6.1).
+In order to disentangle the spin 3
+quantities associated to ˆgl(1) and W∞, we proceed to the next ILW Hamiltonian.
+– 37 –
+
+q → 1 limit of (log Hq)4
+By looking at the local expansion of A4 in appendix E.2, we see
+that the following combination is finite as q → 1:
+B4 ≡ lim
+q→1
+�
+(1 − q)2A4 + α0N(1 − q)A3
+�
+(6.24)
+= N2α3
+0
+2
+�
+m>0
+U1,−mU1,m − α2
+0U1,0
+�
+m>0
+U1,−mU1,m
+(6.25)
+− 3
+2α2
+0
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)
+(6.26)
+= −α2
+0
+2 (U1(U1U1))0 + α2
+0U1,0(U1U1)0 + N2α3
+0
+4
+(U1U1)0 + hw.
+(6.27)
+Its spectrum is given in terms of Bethe roots by
+B4 ⇝ p3,−2 + Nα0p2,−1 + Nα2
+0
+2
+p1,−1 + hw.
+(6.28)
+and the finiteness of the limit in (6.24) requires in addition that
+p3,−3 = −Nα0p2,−2 = (−Nα0)3M1.
+(6.29)
+q → 1 limit of (log Hq)5
+Finally, we can have a look at the local limit of (log Hq)5. The
+quantity that is finite in the local limit is
+B5 ≡ (1 − q)2A5 + 7Nα0
+3
+(1 − q)A4 + 4N2α2
+0
+3
+A3 + N3α3
+0
+6
+A2 − Nα2
+0u1
+3
+A2
+(6.30)
+corresponding to operator
+B5 = −4α2
+0N2
+9
+�
+W4,0 −
+3(N − 3)(α2
+0N2 + 3α2
+0N − 9)
+2N(5α2
+0N3 − 5α2
+0N − 5N − 17)(T∞T∞)0
+�
++ α2
+0
+2N
+�
+(U1(U1(U1U1)))0 − N(U ′
+1U ′
+1)0
+�
++ 2α2
+0N
+3
+T 2
+0 − α2
+0T0(U1U1)0
++ 3α2
+0N
+2
+U1,0W3,0 − α3
+0N3
+12
+W3,0
+(6.31)
+− α2
+0
+N U1,0(U1(U1U1))0 − 19α3
+0N
+36
+(U1(U1U1))0
++ 2α2
+0U 2
+1,0T0 − α3
+0N2
+6
+U1,0T0 − α2
+0N
+4
+T0
++ 4α3
+0N
+3
+U1,0(U1U1)0 + α2
+0(36 + 7α2
+0N3)
+72
+(U1U1)0 + hw.
+It is written manifestly in terms of commuting conserved quantities of W∞ and of the
+Heisenberg algebra. In fact, the operator
+S4 ≡ W4,0 −
+3(N − 3)(α2
+0N2 + 3α2
+0N − 9)
+2N(5α2
+0N3 − 5α2
+0N − 5N − 17)(T∞T∞)0
+(6.32)
+– 38 –
+
+is the unique zero mode of spin 4 local field in W∞ commuting in W3,0. Here W4 is the
+unique spin 4 primary field in W∞ normalized such that
+W4 = U4 + . . .
+(6.33)
+In W∞ we have 4 fields of dimension 4, W4, (T∞T∞), ∂W3 and ∂2T∞. The latter two fields
+are total derivatives so have vanishing zero modes. The requirement of commutativity with
+W3,0 is equivalent to the simple pole of OPE of W3 with our candidate for spin 4 conserved
+quantity being a total derivative. We have
+W3(z)(T∞T∞)(w) ∼ . . . + 4(T∞∂W3)(w)
+z − w
++ . . .
+(6.34)
+W3(z)W4(w) ∼ . . . + 6(N − 3)(α2
+0N2 + 3α2
+0N − 9)
+N(5α2
+0N3 − 5α2
+0N − 5N − 17)
+(T∞∂W3)(w)
+z − w
++ . . .
+(6.35)
+where we did not write explicitly the regular terms, poles of order higher than one and
+operators that are total derivatives (which are in this case fields ∂W5, ∂3W3 and ∂(T∞W3)).
+We see that indeed the combination (6.32) is unique.
+A similar situation happens with spin 4 quantity in the Heisenberg subalgebra. There
+are two dimension 4 local fields modulo total derivatives, (U1(U1(U1U1))) and (∂U1∂U1).
+Their OPE with (U1(U1U1)) is
+(U1(U1U1))(z)(U1(U1(U1U1)))(w) ∼ . . . +
+24N
+5(z − w)∂(U1(U1(U1(U1U1))))(w)
++ 6N2
+z − w(∂3U1(U1U1))(w) + . . .
+(6.36)
+(U1(U1U1))(z)(∂U1∂U1)(w) ∼ . . . + 12N
+z − w(∂U1(∂U1∂U1))(w)
+(6.37)
++ 12N
+z − w(∂2U1(∂U1U1))(w) +
+N2
+5(z − w)∂5U1(w) + . . .
+where we listed all the simple poles. The first and the last term are obviously total deriva-
+tives. Furthermore, the identity
+(∂U1(∂U1∂U1)) + (∂2U1(∂U1U1)) = 1
+2(∂3U1(U1U1)) − 1
+2∂(∂2U1(U1U1)) + ∂(∂U1(∂U1U1))
+(6.38)
+implies that the combination
+(U1(U1(U1U1)))0 − N(∂U1∂U1)0
+(6.39)
+commutes with (U1(U1U1))0 and this is indeed the combination that appears in (6.31). To
+summarize, by taking correctly the local limit q → 1 we obtained from (log Hq)5 and lower
+order ILW Hamiltonians the quantity B5 in (6.31). It is a function of conserved quantities
+of spin up to 4 both in W∞ and in the Heisenberg subalgebra. Furthermore, its spectrum
+(as follows from (5.54)-(5.58)) is given by
+B5 ⇝ p4,−2 + 7α0N
+3
+p3,−1 + 4α2
+0N2
+3
+p2,0 − 2α0p3,−2 − 7α2
+0N
+2
+p2,−1
+(6.40)
+– 39 –
+
++ α3
+0N2(N − 8)
+6
+p1,0 − α2
+0N
+3
+u1p1,0 + α0N(1 + 4α2
+0)
+12
+p1,−1
++ α2
+0N2(4 + 16α2
+0 − 3α2
+0N)
+36
+p0,0 + α3
+0N
+6
+u1p0,0.
+(6.41)
+The finiteness of the limit in (6.30) furthermore requires additional two conditions satisfied
+by pj,k,
+p4,−4 = (−α0N)3p1,−1 = (−α0N)4M1
+(6.42)
+p4,−3 = −7α0N
+3
+p3,−2 − 4α2
+0N2
+3
+p2,−1 − α2
+0N
+6
+(N(N + 1)α0 − 2u1)p1,−1.
+(6.43)
+In order to isolate the contribution of W∞ conserved charge and Heisenberg conserved
+charge, we would need to consider the next quantity, (log Hq)6, but such calculation would
+be technically very difficult.
+W∞ conserved charges and Bethe ansatz equations
+We can now focus on states
+that have no Heisenberg excitations, i.e. states in W∞ subrepresentations. In this case,
+all Bethe roots have finite limit as q → 1 so pj,k = 0 for k < 0. From the expression for
+eigenvalues of B3 we deduce that the operator W3,0 has spectrum
+W3,0 ⇝ −2
+�
+p1,0 + u1
+N M∞
+�
++ α0M∞ + hw.
+(6.44)
+Let’s emphasize again that this equation only holds if there are no Heisenberg excitations,
+i.e. if all Bethe roots are finite in the local limit. It might seem strange at first that the
+formula for the spectrum of W3,0 depends on u1 which is the zero mode of the Heisenberg
+current. But this is actually needed for consistency: Bethe equations are invariant under
+translations of Bethe roots if we simultaneously translate the Coulomb parameters al (this
+symmetry is just the spectral shift symmetry), i.e.
+xj −→ xj − γ
+(6.45)
+al −→ al + γ
+(6.46)
+u1 −→ u1 + Nγ
+(6.47)
+is the symmetry of the equations which simply shifts the zero mode of the Heisenberg field.
+The combination in parentheses in (6.44) is invariant under these translations as it should
+be since the left-hand side does not involve Heisenberg algebra. If we are interested in W∞,
+we can always choose the Coulomb parameters in such a way that u1 = 0 and the formula
+simplifies further.
+Proceeding similarly with spin 4 conserved quantity, we find spectrum
+S4 ⇝ −3
+�
+p2,0 + 2u1
+N p1,0 + u2
+1
+N2 M∞
+�
++ 3α0
+�
+p1,0 + u1
+N M∞
+�
++ 3
+2N (M2
+∞ + 2∆M∞)
++ N3α2
+0 − 9Nα2
+0 − 3N − 3
+8N
+M∞ + hw.
+(6.48)
+– 40 –
+
+Heisenberg conserved charges and Bethe ansatz equations
+Let us now turn to
+the spectrum of Heisenberg conserved quantities. From (6.28) we see that the spectrum of
+(U1(U1U1))0 is given in terms of Bethe roots by
+(U1(U1U1))0 ⇝ − 2
+α2
+0
+p3,−2 − 2N
+α0
+p2,−1 − 4u1
+α0
+p1,−1 − N(N + 1)p1,−1 + hw.
+(6.49)
+In terms of mode expansion, we have
+(U1(U1U1))0 = U 3
+1,0 − N
+4 U1,0 + 6U1,0
+�
+m>0
+U1,−mU1,m
++ 3
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2).
+(6.50)
+The operator on the second line is the cut-and-join operator whose spectrum is known to
+be
+6N
+3
+2
+�
+□∈λ
+(x□ − y□)
+(6.51)
+where λ is a Young diagram parametrizing an excitation of Heisenberg algebra 7.
+The
+prefactor N
+3
+2 is due to the fact that our normalization of U1 is such that the two-point
+function is proportional to N. In order for these two to match, the physical Bethe roots
+need to satisfy a non-trivial constraint,
+6N
+3
+2
+�
+□∈λ
+(x□ − y□) = − 2
+α2
+0
+p3,−2 − 2N
+α0
+p2,−1 + 2u1
+α0
+p1,−1 − N(N + 1)p1,−1.
+(6.52)
+Numerical evidence shows that there is in fact an additional relation
+p3,−2 = −2α0Np2,−1 − α0u1p1,−1 + N(N + 1)α2
+0
+2
+p1,−1
+(6.53)
+so assuming this is true in general, we find a constraint
+6N
+3
+2
+�
+□∈λ
+(x□ − y□) = 2N
+α0
+�
+p2,−1 + 2u1
+N p1,−1
+�
+− 2N(N + 1)p1,−1.
+(6.54)
+Writing this purely in terms of Bethe ansatz equations in manifestly triality and scaling
+invariant way (in particular not restricting to ϵ1ϵ2 = −1), we find a representation-theoretic
+restriction on Bethe roots
+3
+�
+□∈λ
+(x□ − y□) = −
+1
+ϵ1ϵ2ϵ3
+√ψ0
+�
+p2,−1 − 2ψ1
+ψ0
+p1,−1 + 2ψ0ϵ1ϵ2ϵ3p1,−1
+�
+(6.55)
+The quantities ψ0 and ψ1 can be read off from the generating function of lowest weight
+charges A(u) via (6.8). In terms of α0, N and u1 we have
+ψ0 = − N
+ϵ1ϵ2
+(6.56)
+7This formula only applies to Heisenberg algebra and should not be confused with the parametrization
+of states in W1+∞ in the Yangian limit q → 0 or q → ∞.
+– 41 –
+
+ψ1 = u1
+ϵ1ϵ2
++ N(N − 1)
+2
+ϵ3
+ϵ1ϵ2
+.
+(6.57)
+It is quite interesting how the local behaviour of the Bethe roots around q = 1 encodes
+discrete (quantized) quantities such as the eigenvalues of the cut-and-join operator.
+In
+particular, although the Bethe ansatz equations are non-linear algebraic equations, there
+still exist infinitely many constraints on the coefficients of Puiseux expansion around q → 1
+which encode the shape of Young diagram of the associated state of Heisenberg algebra.
+Specialization to Virasoro algebra
+We can specialize the previous discussion to N =
+2 (Virasoro algebra) and compare to results of BLZ. The central charge is conveniently
+parametrized by
+c = 1 − 6(p′ − p)2
+p′p
+= 1 − 6α2
+0
+(6.58)
+and
+ϵ1 =
+�
+p′
+p ,
+ϵ2 = −
+� p
+p′ ,
+ϵ3 = −
+�
+p′
+p +
+� p
+p′ = α0.
+(6.59)
+We choose Coulomb parameters a1 and a2 such that u1 = 0 and express them in terms of
+conformal dimension ∆ of the primary,
+a1 + a2 = 0,
+∆ =
+�
+a1 + ϵ3
+2
+� �
+a1 − ϵ3
+2
+�
+.
+(6.60)
+The function capturing the higher spin charges of the primary state is
+(u + a1 − ϵ3)(u + a2 − ϵ3)
+(u + a1)(u + a2)
+−→ (u − ϵ3)2 − ∆ − ϵ3
+3
+4
+u2 − ∆ − ϵ3
+3
+4
+.
+(6.61)
+It is convenient to shift the Bethe roots according to
+xj = yj + ϵ3
+2
+(6.62)
+so the Bethe equations (5.50) become
+q
+�
+yj − ϵ3
+2
+�2 − ∆ − ϵ2
+3
+4
+�
+yj + ϵ3
+2
+�2 − ∆ − ϵ2
+3
+4
+�
+k̸=j
+(yj − yk + ϵ1)(yj − yk + ϵ2)(yj − yk + ϵ3)
+(yj − yk − ϵ1)(yj − yk − ϵ2)(yj − yk − ϵ3) = 1,
+j = 1, . . . , M
+(6.63)
+or
+q
+�
+yj − ϵ3
+2
+�2 − ∆ − ϵ2
+3
+4
+�
+yj + ϵ3
+2
+�2 − ∆ − ϵ2
+3
+4
+�
+k̸=j
+�
+(yj − yk)2 − ϵ3(yj − yk) − 1
+�
+(yj − yk + ϵ3)
+[(yj − yk)2 + ϵ3(yj − yk) − 1] (yj − yk − ϵ3) = 1,
+j = 1, . . . , M.
+(6.64)
+where in the second equation we eliminated ϵ1 and ϵ2 and expressed everything in terms of
+ϵ3 = α0. These equations have the obvious charge conjugation symmetry (exchanging the
+numerators and the denominators)
+q → q−1,
+yj → −yj.
+(6.65)
+– 42 –
+
+Specializing to quantum KdV charges at q = 1, we find that the spin 3 charge is
+W3,0 ⇝ −2
+M
+�
+j=1
+yj
+(6.66)
+which is required to vanish for Virasoro physical states and for spin 4 charge we find instead
+S4 ⇝ −3
+M
+�
+j=1
+y2
+j + 3
+4(M2 + 2M∆) + α2
+0
+8 M − 9
+16M + hw.
+(6.67)
+This should be compared to formula for spectrum of I3 in (1.16) where for N = 2 we have
+S4 = 1
+4I3.
+(6.68)
+The charge conjugation symmetry flips sign of odd spin generators and keeps the even spin
+generators invariant. In the case of Virasoro algebra there are no odd spin generators so
+Virasoro representations are self-conjugate. The solutions of Bethe equations have to be
+self-conjugate, i.e. given any solution, the Bethe roots can be either zero or come in pairs
+of roots differing by a sign. This is consistent with the form of eigenvalues of W3,0 and S4.
+As an illustration, at level 1, the unique solution of Bethe equations is
+y1 = 0
+(6.69)
+with corresponding S4 eigenvalue
+3
+2∆ + α2
+0
+8 + 3
+16 + hw.
+(6.70)
+which agrees with formula (6.67). At level 2 there are two states, L−2 |∆⟩ and L2
+−1 |∆⟩ and
+from explicit diagonalization we find that S4 has eigenvalues
+3∆ − α2
+0
+2 + 3
+2 ± 3
+8
+�
+32∆ + 4α4
+0 + 4α2
+0 + 1 + hw.
+(6.71)
+The solutions of Bethe ansatz equations are given by pairs of roots {y, −y} with y satisfying
+8y4 − (1 + 2α2
+0)y2 − ∆ = 0.
+(6.72)
+Solving this biquadratic equation and plugging in (6.67), we reproduce exactly (6.71).
+6.1
+Roots of unity and twisted subalgebras
+From the explicit expressions for ILW Hamiltonians we see that q = 1 is not the only
+singular point in the q-plane. In fact, from the term (4.22) we see that all the roots of unity
+are singular at sufficiently high level. Therefore, in the limit of highly excited states, the
+interior |q| < 1 of the unit circle and its exterior |q| > 1 are separated by a dense set of
+singular points.
+– 43 –
+
+Let us choose q0 to be a primitive K-th root of unity (i.e. for q0 = 1 we have K = 1,
+for q0 = −1 we have K = 2, for q0 = ±i we have K = 4 etc.). The ILW Hamiltonian A2
+has simple pole at q = q0 with residue
+lim
+q→q0(q − q0)A2(q) = α0q0
+�
+m>0
+U1,−KmU1,Km.
+(6.73)
+Some of the Bethe roots again diverge in the q → q0 limit with leading singular behaviour
+x ∼
+˜C
+q − q0
++ o((q − q0)−1)
+(6.74)
+where the coefficient ˜C is a common value for all of the singular Bethe roots analogously
+to the situation at q → 1.
+Let us assume analogously to q → 1 case that there is no
+monodromy around q ∼ q0 after we take power sums of Bethe roots. The spectrum of
+(6.73) is given by
+α0q0NK|λ|
+(6.75)
+where λ is the Young diagram labeling a state in the Hilbert space associated to K-twisted
+Heisenberg algebra (i.e. Heisenberg algebra generated by Fourier modes U1,Km, m ∈ Z).
+In our conventions we label the state U1,−K |0⟩ by
+with single box.
+Comparing this
+spectrum with the spectrum of A2 (6.3) which is
+˜C ˜
+M1,
+(6.76)
+where ˜
+M1 is the number of singular Bethe roots, we see that the constant ˜C has to be equal
+to
+˜C = α0q0N K|λ|
+˜
+M1
+.
+(6.77)
+The numerical data at lower levels indicate that every box of λ corresponds to K singular
+roots, i.e. the fraction in equation above is equal to unity and that the constant ˜C is
+˜C = q0α0N
+(6.78)
+which is up to a phase the same result as we found in the local limit q → 1. This value is
+confirmed by the numerical experiments. It would be very interesting to see which other
+Hamiltonians can be extracted from higher Aj and whether twisting by K happens only in
+the Heisenberg subsector or affects also the rest of the algebra.
+7
+Examples of solutions
+Let us discuss some concrete examples of solutions of Bethe ansatz equations (5.50).
+7.1
+Lee-Yang model
+7.1.1
+Argyres-Douglas minimal models
+We will start with the Lee-Yang model with c = − 22
+5 . This model is special in several
+ways. It is at the same time a minimal model of Virasoro algebra as well as of W3 algebra.
+– 44 –
+
+Figure 3: Periodic plane partition corre-
+sponding to ∆ = 0 primary of Lee-Yang
+model
+Figure 4: Periodic plane partition cor-
+responding to ∆ = 0 primary of Ising
+model
+Figure 5: Periodic plane partition cor-
+responding to ∆ = − 1
+5 primary of Lee-
+Yang model
+Figure 6: Periodic plane partition cor-
+responding to level 5 excited state in vac-
+uum representation of Lee-Yang model
+It is also the simplest non-trivial minimal model, having the smallest number of states in
+the vacuum representation. Unlike the more famous Ising model it is non-unitary. Via the
+correspondence between 4d N = 2 superconformal field theories and 2d vertex operator
+algebras [55] it corresponds to the first model in the Argyres-Douglas series, labeled by
+a pair of Dynkin diagrams (A1, A2) [56, 57] and is associated to a plane algebraic curve
+p2 + x3 = 0.
+This minimal model has two primaries, one with ∆ = 0 and one with ∆ = − 1
+5. Recall
+that if we specialize parameters of W∞ by imposing a condition of the form λ3 = N,
+corresponding to truncation to Y00N algebra in the notation of [48, 52], the plane partitions
+– 45 –
+
+corresponding to states in the lowest weight representations are truncated in the direction
+associated to λ3 so that there are at most N layers of boxes [27]. On the other hand,
+if we impose two such conditions in two directions (as we should do in (AN1−1, AN2−1)
+Argyres-Douglas minimal model), the irreducible representations have more states than if
+we naïvely imposed both truncation conditions at the same time. Actually, what happens
+in situations like this is that we effectively develop a periodic direction in the space of plane
+partitions, i.e. the plane partitions should be drawn on a cylinder. The periodic plane
+partition corresponding to Lee-Yang ∆ = 0 lowest weight state is illustrated in Figure 3.
+Counting of states in ∆ = 0 irreducible representation is equivalent to counting of periodic
+configurations of boxes that can be stacked on top of such ground state. We can notice
+several features of this box counting problem. First of all, starting from the corner, we can
+stack horizontally at most three boxes along the brown wall. The fourth box in this direction
+would not be supported from below. This corresponds to W3 algebra truncation with null
+state at level four (corresponding to absent spin 4 generator). Analogously, starting from
+an empty configuration, we can only put two boxes on top of each other vertically. The
+third box would not be supported by anything from behind so it does not satisfy the plane
+partition rule.
+This corresponds to Virasoro truncation of W∞ (and absence of spin 3
+generator of the algebra). But imposing simultaneously two conditions of this type leads
+to periodicity and in turn to a relaxation of these rules. We see that it we consider an L-
+shaped configuration of 4 boxes with three boxes stacked horizontally and 2 vertically, this
+configuration admits addition of fourth box in the horizontal direction (or which is the same
+by periodicity, third box in the vertical direction). Therefore, there is an additional state
+at level 5 that would not be allowed if we would naïvely impose both truncation conditions,
+which would effectively restrict the growth of the plane partitions to 2 × 3 rectangle. The
+configuration of boxes corresponding to this level 5 state in the vacuum representation of
+Lee-Yang is illustrated in Figure 6.
+The fact that the characters of irreducible representations count exactly such periodic
+plane partitions applies to all WN minimal models and all their allowed primaries. The
+choice of a specific minimal model controls the periodicity of the corresponding plane par-
+titions. On the other hand, the choice of a primary is related to the choice of non-trivial
+asymptotics along non-periodic directions (there are generically two such directions for WN
+minimal models but only one such direction in the special case of Argyres-Douglas minimal
+models). In Figure 5 we show the configuration corresponding to the primary field ∆ = − 1
+5
+of the Lee-Yang model. It can be obtained from the configuration of figure 3 by adding an
+infinite column of boxes. The periodicity conditions are not affected. Figure 4 on the other
+hand illustrates the periodic configuration corresponding to the vacuum representation of
+Virasoro c = 1
+2 model, the Ising model. We see that the periodic stairs are offset relative
+to Lee-Yang model. The fact that this model is a Virasoro minimal model can be seen
+from the fact that the stairs have height 2. On the other hand, Ising model as all first
+unitary minimal models of WN series is also a representation of Y012 truncation of W∞.
+Such truncations are characterized by having a null vector at level 6 in the vacuum repre-
+sentation and we can clearly see this null vector by presence of a pit at coordinates (2, 3)
+in the horizontal plane [52, 58].
+– 46 –
+
+The characters of irreducible representations have particularly simple form in the case of
+minimal models of Argyres-Douglas type (AN1−1, AN2−1) corresponding to minimal models
+of simultaneously WN1 and WN2 algebras [27, 59] (we always assume that gcd(N1, N2) = 1).
+In this case, a non-trivial asymptotic is possible only in one of the directions and the allowed
+primaries are thus labeled by Young diagrams that fit in asymptotic N1 × N2 rectangle.
+Since there are
+�N1 + N2
+N1
+�
+=
+�N1 + N2
+N2
+�
+(7.1)
+such Young diagrams, we would expect the same number of primaries. But not all of these
+give inequivalent representations of W∞. Whenever there is a full row or column (of length
+N1 or N2), we can remove it by a shift of the spectral parameter (which affects only the
+zero mode of the Heisenberg algebra). There are N1 + N2 such identifications of primaries
+so in total there are
+(N1 + N2 − 1)!
+N1!N2!
+(7.2)
+inequivalent primaries. The irreducible characters of the corresponding W∞ representation
+can be read off from the asymptotic Young diagram λ as follows: the character is given by
+a hook length formula
+q∆− c
+24 (q; q)∞
+(qN1+N2; qN1+N2)∞
+�
+□∈λ
+1
+(qhook(□); qN1+N2)∞
+.
+(7.3)
+where ∆ is the conformal dimension of the primary which can be combinatorially determined
+as explained for example in [27]. Furthermore
+(a; q)∞ =
+∞
+�
+j=0
+(1 − aqj)
+(7.4)
+is the q-Pochhammer symbol and hook(□) is the (periodic) hook length corresponding to
+the box □ as illustrated in the following diagram for (A1, A2) minimal model:
+1 3 4
+4 1 2
+4 1 3
+2 4 1
+3 4 1
+1 2 4
+1 2 4
+3 4 1
+4 1 2
+1 3 4
+2 3 4
+1 2 3
+4 2 3
+3 1 2
+3 4 2
+2 3 1
+2 3 4
+1 2 3
+1 2 3
+2 3 4
+≃
+≃
+≃
+≃
+≃
+≃
+≃
+≃
+∆ = − 1
+5 :
+∆ = 0 :
+The yellow boxes form the corresponding asymptotic Young diagram λ and they are sepa-
+rated from white boxes by the red line which is the projection of the asymptotic staircase.
+Given a box, its hook length is given by the number of boxes to the left (the arm length)
+plus the number of boxes above (the leg length) plus one (for the box itself). We count the
+boxes until we reach the red line, if needed periodically extending from the left to the right
+and from the top to the bottom. We see that all the Young diagrams related by N1 + N2
+– 47 –
+
+identifications have the same collection of hook lengths. In the case of (A1, A2) minimal
+model we see that
+χ∆=0 =
+q11/60
+(q2; q5)∞(q3; q5)∞
+≃ q11/60(1 + q2 + q3 + q4 + q5 + 2q6 + . . .)
+(7.5)
+χ∆=− 1
+5 =
+q−1/60
+(q; q5)∞(q4; q5)∞
+≃ q−1/60(1 + q + q2 + q3 + 2q4 + 2q5 + 3q6 + . . .).
+(7.6)
+These functions count the states in the corresponding irreducible W∞ representations. To
+get the counting of states in W1+∞, we should multiply these by the Heisenberg contribution
+(q; q)−1
+∞ obtaining expansions
+1
+�∞
+n=1(1 − qn)χ∆=0 ∼ 1 + q + 3q2 + 5q3 + 9q4 + 14q5 + . . .
+(7.7)
+1
+�∞
+n=1(1 − qn)χ∆=− 1
+5 ∼ 1 + 2q + 4q2 + 7q3 + 13q4 + 21q5 + . . .
+(7.8)
+which will be useful in the following. As another example, for W3 ∩ W4 minimal model
+(corresponding to (A2, A3) Argyres-Douglas with c∞ = − 114
+7 ) the primary ∆ = − 4
+7 with
+asymptotic
+has hook lengths
+2 3 5 6
+1 2 4 5
+5 6 1 2
+corresponding to W∞ character
+q3/28
+(q; q7)∞(q2; q7)2∞(q5; q7)2∞(q6; q7)∞
+.
+(7.9)
+7.1.2
+Solutions of Bethe ansatz equations for ∆ = − 1
+5
+Now that we know enough information about the representations and their characters, we
+can have a look at the corresponding solutions of Bethe ansatz equations (5.50). First of
+all we make a choice of the parameters of the algebra. Let us choose
+ϵ1 = 2,
+ϵ2 = 3,
+ϵ3 = −5
+(7.10)
+with ψ0 = 1
+5. The corresponding λ-parameters are
+λ1 = 3,
+λ2 = 2,
+λ3 = −6
+5
+(7.11)
+and the W∞ central charge is
+c∞ = (λ1 − 1)(λ2 − 1)(λ3 − 1) = −22
+5
+(7.12)
+which is exactly the central charge of the non-unitary Lee-Yang model. As for the function
+parametrizing the lowest weights, we choose
+A(u) −→ (u − 5)(u − 6)
+(u − 2)(u − 3).
+(7.13)
+– 48 –
+
+As discussed in [52], this can be done from the point of view of second asymptotic direction,
+i.e. Virasoro algebra (N ↔ λ2) where we would write
+(u − 2 − ϵ2)(u − 3 − ϵ2)
+(u − 2)(u − 3)
+= (u − 5)(u − 6)
+(u − 2)(u − 3)
+(7.14)
+or from the point of view of first direction, i.e. W3 algebra (N ↔ λ1) where the factorization
+is instead
+(u − 2 − ϵ1)(u − 3 − ϵ1)(u − 4 − ϵ1)
+(u − 2)(u − 3)(u − 4)
+= (u − 5)(u − 6)
+(u − 2)(u − 3).
+(7.15)
+The requirement of factorizability both as (7.14) and (7.15) (i.e. corresponding to both
+truncations) determines all allowed primaries [52]. In our case there are only two of them
+up to constant shifts of u-parameter (which does not change the W∞ representation but
+changes the lowest weight with respect to Heisenberg algebra).
+Level 1
+At level 1, there is a single Bethe ansatz equation
+q(x1 − 5)(x1 − 6)
+(x1 − 2)(x1 − 3) = 1
+(7.16)
+with two solutions
+5 − 11q +
+�
+1 + 34q + q2
+2(1 − q)
+≃ 3 + 6q − 66q2 + 1158q3 + . . .
+(7.17)
+and
+5 − 11q −
+�
+1 + 34q + q2
+2(1 − q)
+≃ 2 − 12q + 60q2 − 1164q3 + . . . .
+(7.18)
+We see that in the Yangian limit q → 0 the solutions are analytic and the Bethe roots
+approach the weighted coordinates of positions where we can put the boxes: choosing the
+corner of the vacuum periodic plane partition to be at coordinates (0, 0, 0), in the ∆ = − 1
+5
+we can put the first box either at coordinates (1, 0, 0) or (0, 1, 0). The weighted coordinates
+of these are ϵ1 = 2 and ϵ2 = 3 which are exactly the limiting values of the Bethe roots
+as q → 0. We could similarly study the behaviour as q → ∞ where we would find the
+conjugate Yangian prediction for these limiting values.
+In the local limit q → 1, we have
+5 − 11q +
+�
+1 + 34q + q2
+2(1 − q)
+≃ 4 − 1
+3(1 − q) − 1
+6(1 − q)2 + . . .
+(7.19)
+and
+5 − 11q −
+�
+1 + 34q + q2
+2(1 − q)
+≃ −
+6
+1 − q + 7 + 1
+3(1 − q) + 1
+6(1 − q)2 + . . . .
+(7.20)
+We see that the first of these is regular as q → 1 and so it corresponds to W∞ excitation.
+On the other hand, the second solution has a simple pole as q → 1 with residue given by
+−ψ0ϵ1ϵ2ϵ3 so it corresponds to a Heisenberg excitation in line with the general discussion
+in section 6.
+– 49 –
+
+Finally, we have in addition two branch points in the q-plane at points
+q = −17 ± 12
+√
+2
+(7.21)
+(note that these are inverse of one another as required by charge conjugation). These two
+points both lie on the negative real axis and as we continue the solutions of Bethe equations
+around them, the solutions get exchanged. This shows that the two sheets corresponding
+to two different states at level 1 actually connect as we analytically continue in q-parameter
+space, so there is a single connected Riemann surface covering the q-plane which captures
+both Bethe roots at this level. We also see that the excitation purely in Heisenberg sub-
+algebra can be transformed to purely W∞ excitation by analytic continuation in the twist
+parameter q (and vice versa), so for generic values of q we cannot expect decoupling of these
+degrees of freedom.
+Note also that for q equal to one of these two branch points the corresponding eigen-
+states of ILW Hamiltonians have identical spectrum of all the conserved charges. In the
+case of level 1 states discussed now the fact that by tuning one complex parameter q we
+can make two Bethe roots agree is not so surprising, but as we will see such phenomenon
+persists also at higher excited levels although generically we would expect these to be of
+a higher codimension. But of course our system of algebraic equations is far from being a
+generic one, so many special coincidencies are happening.
+Level 2
+At next level, each solution of BAE is given by a pair of Bethe roots (x1, x2)
+solving a system of equations
+1 = q(x1 − 5)(x1 − 6)
+(x1 − 2)(x1 − 3)
+(x1 − x2 + ϵ1)(x1 − x2 + ϵ2)(x1 − x2 + ϵ3)
+(x1 − x2 − ϵ1)(x1 − x2 − ϵ2)(x1 − x2 − ϵ3)
+(7.22)
+1 = q(x2 − 5)(x2 − 6)
+(x2 − 2)(x2 − 3)
+(x2 − x1 + ϵ1)(x2 − x1 + ϵ2)(x2 − x1 + ϵ3)
+(x2 − x1 − ϵ1)(x2 − x1 − ϵ2)(x2 − x1 − ϵ3).
+(7.23)
+We see that we have a system of two equations of fifth degree for two unknowns which is
+much more complicated than a single quadratic equation that we were solving previously.
+There are various possible approaches to solve these equations.
+The most naïve one is to use Newton’s method to find numerically an approximate
+solution starting from a random initial seed. In this way we find generically 16 solutions.
+Since the equations themselves are invariant under the exchange x1 ↔ x2, the solutions
+will also form either pairs of solutions related by this exchange or solutions with x1 = x2.
+From the numerics we find three groups of solutions that do not mix among each other as
+we analytically continue in q. The first group are three solutions
+(2, 5),
+(3, 5)
+(3, 6)
+(7.24)
+which are q-independent (and can be associated to null states). Next there are two degen-
+erate solutions with x1 = x2 which are given by
+x1 = x2 = 5 + 11q ±
+�
+1 − 34q + q2
+2(1 + q)
+.
+(7.25)
+– 50 –
+
+Finally we have four solutions which are q-dependent and which have x1 ̸= x2 for generic q.
+There is probably no explicit formula for these eight Bethe roots, but it is precisely these
+that correspond to four states in the irreducible representation at level 2 and this is why
+in the following we will mainly focus on these. The Bethe roots corresponding to states in
+irreducible representations of W1+∞ will be called physical in the following.
+We can also try to learn something about the solutions analytically. We can eliminate
+one of the variables using the resultant of the two Bethe equations. The resultant of BAE
+with respect to x2 is a polynomial of degree 16 in x1 (with coefficients still depending on
+q). This polynomial has linear factors corresponding to the integer roots x1 ∈ (2, 3, 5, 6)
+with multiplicity 1 or 2. Next we have a quadratic factor
+(1 + q)x2
+1 − (5 + 11q)x1 + 6 + 30q
+(7.26)
+whose solutions are the degenerate roots (7.25). Finally, there is an irreducible degree 8
+polynomial
+(q − 1)5(q + 1)2x8
+1 − (q − 1)4(q + 1)
+�
+53q2 + 18q − 11
+�
+x7
+1
++ (q − 1)3 �
+1207q4 + 828q3 − 446q2 − 180q + 31
+�
+x6
+1
+− (q − 1)2 �
+15443q5 + 571q4 − 8062q3 + 226q2 + 395q + 67
+�
+x5
+1
++ 4(q − 1)
+�
+30388q6 − 18560q5 − 10357q4 + 4678q3 + 53q2 + 400q − 122
+�
+x4
+1
+− 4
+�
+150836q7 − 190341q6 + 25286q5 + 24859q4 − 4261q3 + 2758q2 − 1509q + 148
+�
+x3
+1
++ 48
+�
+38460q7 − 35489q6 + 3469q5 + 1592q4 − 674q3 + 479q2 − 41q − 20
+�
+x2
+1
+− 144
+�
+22125q7 − 13310q6 + 583q5 + 1020q4 − 756q3 + 119q2 + 66q − 19
+�
+x1
++ 1728
+�
+1375q7 − 425q6 − 55q5 + 132q4 − 60q3 + q2 + 5q − 1
+�
+(7.27)
+whose roots are the 4 pairs of non-degenerate q-dependent Bethe roots that we identify
+with the physical states. Solving this degree 8 equation for x1 determines x1 as a function
+of q. Finally by calculating the greatest common divisor with respect to x2 of Bethe ansatz
+equations reduces them to a linear equation for x2 which allows us to uniquely determine
+x2 in terms of x1 and q. The formula is
+x2 =
+N
+D1D2
+N = (q − 1)3(q + 1)2x7
+1 − (q − 1)2(q + 1)
+�
+25q2 + 6q − 7
+�
+x6
+1
++ 3(q − 1)
+�
+43q4 + 36q3 − 2q2 − 12q − 5
+�
+x5
+1
++
+�
+1993q5 − 2059q4 − 2186q3 + 1958q2 + 373q − 295
+�
+x4
+1
+− 2
+�
+15839q5 − 10325q4 − 10612q3 + 5956q2 + 1037q − 599
+�
+x3
+1
++ 12
+�
+15315q5 − 7279q4 − 6216q3 + 2648q2 + 333q − 193
+�
+x2
+1
+− 72
+�
+6975q5 − 2405q4 − 1536q3 + 560q2 + 37q − 31
+�
+x1
++ 864(5q + 1)
+�
+125q4 − 55q3 − 2q2 + 5q − 1
+�
+(7.28)
+D1 = (q − 1)x2
+1 + (5 − 11q)x1 + 6(5q − 1)
+D2 =
+�
+1 − q2�2 x4
+1 +
+�
+1 − q2� �
+25q2 − 7
+�
+x3
+1 + 4
+�
+58q4 − 41q2 + 4
+�
+x2
+1
+– 51 –
+
+− 12
+�
+79q4 − 24q2 + 1
+�
+x1 + 144q2 �
+10q2 − 1
+�
+.
+We see that it is a complicated yet very explicit map which we can use to find the second
+Bethe root once we know the first one (for example from the resultant), i.e. we can use this
+map to pair solutions of (7.27) to form solutions of BAE. By construction the corresponding
+transformation of Bethe roots is involutive as it must be since the Bethe roots appear in
+pairs.
+In the Yangian limit q → 0, the zeros of (7.27) can found using ordinary power series:
+the eight solutions are
+�
+−3 − 18
+7 q − 55458
+1715 q2 + 6113358
+420175 q3 + O(q4)
++2 − 144
+5 q2 + 1692
+175 q3 + O(q4)
+�
+−2 − 3q + 249
+20 q2 − 4839
+200 q3 + O(q4)
++3 + 84
+5 q2 − 459
+50 q3 + O(q4)
+�
++2 + 3q + 555
+4 q2 + 22623
+8
+q3 + O(q4)
++3 − 24q + 24q2 − 15789
+2
+q3 + O(q4)
+(7.29)
+�
++2 − 12q2 + 2160
+7 q3 + O(q4)
++4 + 60
+7 q − 55176
+343 q2 + 79819980
+16807 q3 + O(q4)
+The eight roots of the resultant were paired into 4 solutions of Bethe ansatz equations using
+equation (7.28) which gives us the second Bethe root once we know the first one. We can
+identify the Yangian q → 0 limit of these solutions with configurations of boxes in periodic
+plane partitions.
+The positions in which we can put two boxes and the corresponding
+Yangian Bethe roots are
+(ϵ1, 2ϵ1) = (2, 4)
+(7.30)
+(ϵ1, ϵ1 + ϵ3) = (2, −3)
+(7.31)
+(ϵ2, ϵ2 + ϵ3) = (3, −2)
+(7.32)
+(ϵ1, ϵ2) = (2, 3)
+(7.33)
+which are exactly the q → 0 limits of the perturbative solutions that we found. A similar
+analysis would apply to q → ∞ where we would find a very similar picture corresponding
+to a conjugate representation (which in this case is the same one) up to a spectral shift.
+We can also use the analytic techniques to find points in q-plane around which the so-
+lutions have non-trivial monodromy, i.e. points in q-plane such that analytically continuing
+around them allows us to go from one solution of Bethe ansatz equations to another. First
+of all, the solutions of the three groups of solutions cannot mix by monodromy because this
+would not be compatible with analytic continuation in q (i.e. analytic continuation around
+a point in q-plane of a solution with non-trivial q-dependence cannot produce q-independent
+solution and analytic continuation of solution satisfying x1 = x2 will never result in solution
+that does not satisfy this constraint). The most interesting solutions which are those that
+solve (7.27), i.e. the physical solutions. The discriminant of this equation is q-dependent
+– 52 –
+
+-0.15
+0.05
+0.25
+0.45
+0.65
+-0.15
+0.05
+0.25
+0.45
+0.65
+-4
+-2
+2
+4
+-5
+-4
+-3
+-2
+-1
+1
+Figure 7: An illustration of non-trivial homotopy of solutions of Bethe ansatz equations
+around q = q∗ ∼ 0.168469 + 0.432772i. The left figure shows the curve in the q-plane. The
+red dots are zeros of the discriminant so around these points the monodromy is potentially
+non-trivial. The curve on the left encloses only one such singular point. The figure on the
+right shows how four pairs of Bethe roots evolve in the complex plane. We start at q = 0
+with Yangian solutions blue → (2, 4), red → (−2, 3), yellow → (2, −3) and green → (2, 3)
+and go around q = q∗ and return back to q = 0. We see that while the yellow and green
+Bethe roots go back to their original values, the red and green Bethe roots are instead
+pairwise exchanged.
+polynomial which tells us where in q-plane there can be a non-trivial monodromy. The
+discriminant factorizes such that the factors are of the following form:
+D ∼ F 30
+1 F 10
+2 F 4
+3 F4F 2
+5 F 2
+6
+F1 = q
+F2 = q − 1
+F3 = q + 1
+F4 = 25q4 − 1180q3 − 282q2 − 1180q + 25
+F5 = q8 + 59q7 + 55q6 − 119q5 + 494q4 − 119q3
+(7.34)
++ 55q2 + 59q + 1
+F6 = 49q12 + 2753q11 + 6044q10 + 250824q9 + 67633q8
++ 669175q7 + 1739524q6 + 669175q5 + 67633q4
++ 250824q3 + 6044q2 + 2753q + 49
+All these factors are palindromic polynomials, i.e. q is a root of these if and only if q−1 is
+a root which is compatible with the charge conjugation symmetry of the algebra. Since ϵj
+parameters as well as the parameters characterizing charges of the lowest weight vector are
+real, the roots of these polynomials also appear in complex conjugate pairs.
+– 53 –
+
+We can use the homotopy method to study the monodromy of the solutions. Since at
+the Yangian points q → 0 or q → ∞ we can solve the Bethe ansatz equations exactly, we
+can start from there, slowly deforming the homotopy parameter q in the complex plane and
+at every step using Newton’s method to update the solution. Since the Newton’s method
+converges very rapidly away from special points in the q-plane, this is a very convenient way
+to solve BAE at any given value of q. Starting with four physical solutions around q = 0, we
+can study what happens as we go around zeros of the discriminant (7.34). It turns out that
+q = 0 (zero of F1) is a regular point where our solutions have no monodromy and actually we
+can find a power series solutions around this point (converging up to nearest singular point
+in q-plane). The local point q = 1 has monodromy associated to it, but this monodromy
+is such that only two Bethe roots of a given solution of BAE get exchanged. The solutions
+of BAE corresponding to different physical states do not get mixed as we go around q = 1.
+Also, as discussed in detail in the previous section, some solutions of BAE blow up as we
+approach q = 1. These Bethe roots correspond to excitations of the Heisenberg subalgebra.
+We have a similar situation around q = −1, but at this level there is no monodromy (since
+there can be only one excitation of the twist 2 Heisenberg subalgebra). For values of q
+that are roots of F4 the monodromy is similarly only exchanging two Bethe roots in a
+given solution. There is no monodromy at all associated to roots of F5. Finally, the most
+interesting case are the roots of F6. Around all these points the solutions of Bethe ansatz
+equations are exchanged in a transitive manner, i.e. starting with any solution around q = 0,
+by a suitable path around roots of F6 we can get any other of the four physical solutions.
+This is somewhat analogous to the situation in other integrable models [54] where various
+eigenstates of the set of commuting operators are connected as we analytically continue
+in the parameters. One example of such monodromy around q ∼ 0.168469 + 0.432772i is
+shown in Figure 7. To summarize, the monodromy of solutions of (7.27) as we vary q must
+preserve the pairs of Bethe roots in a given solution, so the monodromy group is reduced
+from the generic S8 to S4
+2 ⋊ S4.
+Finally we want to study the solutions around q = ±1.
+At local point q = 1, we
+expect to find two solutions whose both Bethe roots blow up (corresponding to
+and
+excitations of Heisenberg algebra), one solution where only one Bethe root blows up while
+the other one corresponds to level 1 state of W∞ and finally one finite solution corresponding
+to level 2 state in W∞. This is exactly the case as we can see from the solutions
+�
+�
+�
+−
+6
+1−q +
+√
+3
+4√
+5(1 − q)− 1
+2 +
+�
+7 −
+√
+5
+2
+�
+− 1
+4
+�
+−12 + 27
+√
+5(1 − q)
+1
+2 + O((1 − q)1)
+−
+6
+1−q −
+√
+3
+4√
+5(1 − q)− 1
+2 +
+�
+7 −
+√
+5
+2
+�
++ 1
+4
+�
+−12 + 27
+√
+5(1 − q)
+1
+2 + O((1 − q)1)
+�
+�
+�
+−
+6
+1−q + i
+√
+3
+4√
+5(1 − q)− 1
+2 +
+�
+7 +
+√
+5
+2
+�
+− i
+4
+�
+−12 + 27
+√
+5(1 − q)
+1
+2 + O((1 − q)1)
+−
+6
+1−q − i
+√
+3
+4√
+5(1 − q)− 1
+2 +
+�
+7 +
+√
+5
+2
+�
++ i
+4
+�
+−12 + 27
+√
+5(1 − q)
+1
+2 + O((1 − q)1)
+�
+−
+6
+1−q + 7 − 4
+3(1 − q) − 2
+3(1 − q)2 + O((1 − q)3)
+4 − 1
+3(1 − q) − 1
+6(1 − q)2 + O((1 − q)3)
+– 54 –
+
+�
+4 −
+√
+52 − 3
+4(1 − q) − 3
+64(8 −
+√
+10)(1 − q)2 + O((1 − q)3)
+4 +
+√
+52 − 3
+4(1 − q) − 3
+64(8 +
+√
+10)(1 − q)2 + O((1 − q)3).
+(7.35)
+As we go around q = 1, the only monodromy that is there is exchanging the Bethe roots in
+a given solution of Bethe ansatz equations, i.e. symmetric polynomials of Bethe roots do
+not undergo any monodromy and we expect this to be the general behaviour.
+By using the homotopy to continue four solutions corresponding to four level 2 states
+from q = 0 to q = −1, we see that three of the solutions have usual Taylor series expansion
+around q = −1 and one solution that blows up as q → −1 (corresponding to twisted
+Heisenberg algebra eigenstate),
+�
+4 +
+�
+3 −
+√
+5 + 1
+24
+�
+9
+√
+5 − 53
+�
+(q + 1) + O((1 + q)2)
+4 −
+�
+3 +
+√
+5 + 1
+24
+�
+−9
+√
+5 − 53
+�
+(q + 1) + O((1 + q)2)
+�
+4 −
+�
+3 −
+√
+5 + 1
+24
+�
+9
+√
+5 − 53
+�
+(q + 1) + O((1 + q)2)
+4 +
+�
+3 +
+√
+5 + 1
+24
+�
+−9
+√
+5 − 53
+�
+(q + 1) + O((1 + q)2)
+�
+4 −
+√
+7
+2 + 9
+8(q + 1) + O((1 + q)2)
+4 +
+√
+7
+2 + 9
+8(q + 1) + O((1 + q)2)
+(7.36)
+�
+�
+�
+−
+6
+1+q + 7 −
+√
+19
+2
+− 11
+24(1 + q) −
+�
+11
+48 +
+5
+16
+√
+19
+�
+(1 + q)2 + O((1 + q)3)
+−
+6
+1+q + 7 +
+√
+19
+2
+− 11
+24(1 + q) −
+�
+11
+48 −
+5
+16
+√
+19
+�
+(1 + q)2 + O((1 + q)3).
+We see that the twisted level 2 Heisenberg excitation has the same singular behaviour (with
+the same residue) as q → −1 as the usual Heisenberg excitations have for q → 1. Although
+it corresponds to a lowest excitation of the twisted Heisenberg algebra of even modes, at
+the level of Bethe ansatz equations it is represented by a pair of singular Bethe roots.
+7.1.3
+Solutions of Bethe ansatz equations for ∆ = 0
+Let us solve the Bethe ansatz equations also for the other primary, the translation-invariant
+vacuum state ∆ = 0. In this case, the generating function of Yangian charges of the lowest
+weight state is simply
+u + ψ0ϵ1ϵ2ϵ3
+u
+= u − 6
+u
+(7.37)
+so Bethe ansatz equations are of one lower degree which makes the analysis simpler.
+Level 1
+The Bethe equation is simply
+1 = qx1 − 6
+x1
+(7.38)
+so we have only one solution with Bethe root
+x1 = − 6q
+1 − q
+(7.39)
+whose only singularity is at the local point q = 1.
+It corresponds to first Heisenberg
+excitation.
+– 55 –
+
+Level 2
+At level 2 Bethe equations are
+1 = q x1 − 6
+x1
+(x1 − x2 + ϵ1)(x1 − x2 + ϵ2)(x1 − x2 + ϵ3)
+(x1 − x2 − ϵ1)(x1 − x2 − ϵ2)(x1 − x2 − ϵ3)
+(7.40)
+1 = q x2 − 6
+x2
+(x2 − x1 + ϵ1)(x2 − x1 + ϵ2)(x2 − x1 + ϵ3)
+(x2 − x1 − ϵ1)(x2 − x1 − ϵ2)(x2 − x1 − ϵ3).
+(7.41)
+Numerical solution indicates that there are three pairs of non-trivial q-dependent solutions
+corresponding to three physical states at level 2 in the vacuum representation and one
+degenerate solution with x1 = x2. The factor of resultant corresponding to physical states
+is degree 6 polynomial
+(q − 1)4(q + 1)2x6
+1 − 12(q − 1)3(q + 1)(3q + 1)qx5
+1
++(q−1)2 �
+521q4 + 360q3 + 2q2 − 19
+�
+x4
+1−6(q−1)
+�
+649q5 + 43q4 − 40q3 − 48q2 − 33q + 5
+�
+x3
+1
++ 36
+�
+441q4 − 246q3 + 29q2 − 76q − 4
+�
+q2x2
+1 − 216
+�
+155q2 − 34q + 23
+�
+q4x1 + 28512q6
+(7.42)
+whose 6 roots correspond to three pairs of Bethe roots. The identification between the pairs
+is obtained as before by taking the greatest common divisor of Bethe equations and we find
+a fractional linear map
+x2 =
+6q2(x1 − 6)
+(q2 − 1)x1 − 6q2
+(7.43)
+which can be checked to be involutive on the set of solutions of (7.42). The discriminant of
+the relevant factor of the resultant (corresponding to Bethe roots that are not identically
+equal) is
+D ∼ q12(1 − q)18(1 + q)4(5 − 66q + 5q2)×
+× (196 + 8923q + 12800q2 + 59842q3 + 12800q4 + 8923q5 + 196q6)2
+(7.44)
+and the points in the q-plane where there are non-trivial monodromies are different than
+the ones of ∆ = − 1
+5 representation.
+Level 3
+The vacuum representation ∆ = 0 is slightly simpler than the primary ∆ = − 1
+5
+due to the fact that the generating function of Yangian lowest weight charges
+A(u) = u − 6
+u
+(7.45)
+has only single zero and a single pole. The number of zeros and poles of this function is
+the quantity that (along with the level M) has the main influence on the degrees of Bethe
+ansatz equations and the associated difficulty of solving it. The vacuum representation of
+W1+∞ would have six states at level 3, but since we have a singular vector at level 3 (due
+to Virasoro condition λ2 = 2), we will only have five states.
+The naïve numerical solution of the system of level 3 Bethe ansatz equations fails due
+to the fact that at this level there appear continuous families of solutions. In fact, consider
+– 56 –
+
+a solutions of the form
+�
+�
+�
+�
+�
+�
+�
+x1
+=
+f(q)
+x2
+=
+f(q) + ϵ1 = f(q) + 2
+x3
+=
+f(q) + ϵ1 + ϵ2 = f(q) + 5
+(7.46)
+�
+�
+�
+�
+�
+�
+�
+x1
+=
+f(q)
+x2
+=
+f(q) + ϵ2 = f(q) + 3
+x3
+=
+f(q) + ϵ1 + ϵ2 = f(q) + 5
+(7.47)
+i.e. triples of Bethe roots satisfying a non-trivial resonance condition (related to the wheel
+condition in shuffle algebra [60]). It is clear that these are solutions of Bethe ansatz equa-
+tions for any function f(q) if we write these equations in the polynomial form, i.e. if we
+move all the numerators on one side and denominators on the other side. Since there is a
+one-parametric family of such solutions for any value of q, if we apply Newton’s method
+with random initial seed, we will almost surely end up with a solution of this kind.
+There is no problem with the homotopy method. The solutions of BAE at q = 0 are
+either solutions of the family of solutions written above, or one of the following families of
+discrete solutions:
+1. solutions corresponding to physical states in the irreducible representation
+(−10, −5, 0),
+(−5, 0, 2),
+(−5, 0, 3),
+(0, 2, 3),
+(0, 2, 4)
+(7.48)
+2. null state solution (remnant of missing 6th state in the vacuum representation)
+(0, 3, 6)
+3. solutions
+(−3, 0, 2),
+(−2, 0, 3),
+(−5, −3, 0),
+(−5, −2, 0),
+(0, 2, 5),
+(0, 3, 5)
+4. solutions with degenerate Bethe roots
+(−5, −5, 0),
+(−5, 0, 0),
+(0, 0, 2),
+(0, 0, 3),
+(0, 2, 2),
+(0, 3, 3)
+We can project the set of Bethe solutions corresponding to level 3 states in the vacuum
+module (case 1 at q = 0) to complex line (eliminating variables x2 and x3 from Bethe
+equations) using resultants. As a first step in the reduction, we evaluate the resultant for
+the first and second Bethe equation with respect to variable x3 and the largest irreducible
+factor is a polynomial in x2 of degree 15 (with coefficients which are polynomials in x1 and
+q). Similarly, by taking the resultant of first and third Bethe equation in variable x3 and
+extracting the largest irreducible factor, we get another polynomial of degree 15 in x2 with
+coefficients which are polynomials in x1 and q. Note that if we did the same procedure
+with second and third Bethe equations, we would get a polynomial in x2 of degree 24.
+– 57 –
+
+-1.5
+-1.0
+-0.5
+0.5
+1.0
+1.5
+-1.5
+-1.0
+-0.5
+0.5
+1.0
+1.5
+Figure 8: Zeros of the discriminant of the polynomial whose zeros are exactly the 15 Bethe
+roots of the Lee-Yang vacuum representation at level 3. Only around these points in the
+q-plane the Bethe roots can have non-trivial monodromy. The zeros are symmetric under
+complex conjugation q → ¯q as well as under spherical inversion q → q−1 so we do not show
+most of the zeros outside of the unit disc. Note that apart from the special points q = 1
+and q = −1 which lie on the unit circle, there are also other special points with modulus
+|q| = 1, in particular the cubic roots of unity q = e±2πi/3.
+Now we calculate the resultant with respect to x2 of the two degree 15 polynomials in x2
+that we found before. The resulting polynomial is a polynomial of large degree in x1 with
+coefficients that are polynomials in q. The largest irreducible factor is of degree 120 in x1,
+but this is not the factor we are interested in (we can for example check that the solutions
+obtained by homotopy from the physical solutions (7.48) are not zeros of this factor). The
+factor that we are interested in is the irreducible factor of degree 15 in x1. Its explicit form
+is rather complicated and is given in appendix F.1.1. For a given q its roots are exactly the
+five triples of Bethe roots corresponding to five solutions of BAE associated to five physical
+level 3 states. Having a single polynomial whose roots are in one-to-one correspondence
+with the physical Bethe roots is very convenient starting point to study Puiseux series
+expansions of the solutions around any value of q, for example using the Newton’s polygon.
+Having an irreducible polynomial with these properties is also useful in order to show that
+the analytic continuation in q parameter does not mix these physical solutions of BAE with
+other solutions. Discriminant of this polynomial tells us around which points in the q-plane
+the solutions undergo a non-trivial monodromy. There are in fact 91 such special points
+and their positions in the q-plane are illustrated in Figure 8.
+– 58 –
+
+The expansion of the solutions around q = 0 produces is a regular Taylor series ex-
+pansion with rational coefficients as shown in appendix F.1.2. The expansion of physical
+solutions around local point q = 1 is given in appendix F.1.3. The first of these solutions
+has limit (0, 3, 6) as q → 1 which coincides with the constant q-independent solution (0, 3, 6)
+but for q ̸= 1 these are different solutions of BAE. They lie on different branches (different
+factors of the resultant) so they cannot mix as we move around q-plane (but this does not
+prevent them from coinciding at special values of q). The second solution corresponds to
+one Heisenberg root and level 2 excitation of W∞. The third solution has three Heisenberg
+roots which are cyclically exchanged as we go around q = 1 and corresponds to state
+of Heisenberg algebra. The last two states have also three Heisenberg roots, but the mon-
+odromy around q = 1 only exchanges two of their roots while the third root is single-valued.
+These correspond to
+and
+excitations of Heisenberg algebra.
+Level 3 - twisted local limit q → −1
+The limit q → −1 is also a singular limit for some
+Bethe roots, concretely for those which are associated to excitations of even mode subalgebra
+of the Heisenberg algebra. The degree 15 factor of the resultant given in appendix F.1.1
+simplifies to
+(x−3)3(28−78x+157x2−48x3+4x4)(17424−6864x+2332x2−612x3+141x4−18x5+x6)
+(7.49)
+which is of degree 13, i.e.
+we lost two roots (corresponding to Bethe roots that blew
+up in the limit). Using the homotopy method, we see that the roots of discriminant are
+combined to solutions of BAE in the following manner: the six roots of the sextic factor give
+two complex conjugate solutions of Bethe ansatz equations. The four roots of the quartic
+equation together with two roots x = 3 give other two complex conjugate solutions of BAE.
+The last physical solution of BAE in q → −1 limit has Laurent expansion
+�
+�
+�
+�
+�
+�
+�
+x1
+= −
+6
+q+1 + 12+
+√
+19
+2
+− 59
+24(q + 1) + O((q + 1)2)
+x2
+= −
+6
+q+1 + 12−
+√
+19
+2
+− 59
+24(q + 1) + O((q + 1)2)
+x3
+= 3 − 3
+2(q + 1) − 3
+4(q + 1)2 + O((q + 1)3).
+(7.50)
+The Bethe roots x1 and x2 are singular and correspond to level 2 excitation of the Heisen-
+berg algebra and the third root corresponds to the excitation of the algebra which is the
+commutant of the twisted Heisenberg algebra in W1+∞.
+Level 3 - other twisted local limits q → e±2πi/3
+There are other points in the q-plane
+where one of the Bethe roots becomes singular. The easiest way of seeing such points is
+by looking at the leading coefficient x15 in the resultant characterizing all physical Bethe
+roots. Bethe roots blow up exactly when this leading coefficient vanishes. In the example
+studied here the number of Bethe roots that blow up is captured by this polynomial in q:
+we have
+β15 = (q − 1)10(q + 1)2(q2 + q + 1)3
+(7.51)
+and we can see that indeed ten Bethe roots blow up as q → 1 and two Bethe roots blow up
+as q → −1 as confirmed by explicit calculations above. We also see that three Bethe roots
+– 59 –
+
+should blow up when q → e±2πi/3. This is exactly what is happening. The corresponding
+singular solution around q = e2πi/3 has Bethe roots of the form
+− ψ0ϵ1ϵ2ϵ3e2πi/3
+q − e2πi/3
++ γ0 + O((q − e2πi/3)1)
+(7.52)
+where γ0 are the three roots of the equation
+γ3
+0 − 18γ2
+0 + 89γ0 − 102
+√
+3 + 10i = 0.
+(7.53)
+Since the leading and subleading terms have no monodromy around q = e2πi/3 and distin-
+guish the three roots, there is no monodromy at all orders, i.e. we have Laurent expansion
+of the Bethe roots in (q − e2πi/3).
+7.2
+Perturbative expansion at q = 0 and residue formula
+Just as the constant coefficient in q → 0 expansion can be read off directly from the
+combinatorics of periodic plane partitions, so can be the O(q) coefficient: it is simply given
+by the residue of the generating function of the Yangian higher spin charges. Consider
+for concreteness level 3 descendants of ∆ = 0 primary in Lee-Yang model. We have five
+physical solutions as listed in (7.48). Their corresponding generating functions of Yangian
+higher spin charges are
+(0, ϵ1, 2ϵ1) = (0, 2, 4) ⇝ ψ(u) = (u − 9)(u − 1)(u + 2)
+(u − 4)(u − 3)(u + 5)
+(7.54)
+(0, ϵ3, 2ϵ3) = (0, −5, −10) ⇝ ψ(u) = (u − 6)(u − 5)(u + 12)(u + 13)
+(u − 3)(u − 2)(u + 10)(u + 15)
+(7.55)
+(0, ϵ1, ϵ2) = (0, 2, 3) ⇝ ψ(u) =
+(u − 8)(u − 7)(u − 1)u(u + 1)
+(u − 5)(u − 4)(u − 3)(u − 2)(u + 5)
+(7.56)
+(0, ϵ1, ϵ3) = (0, 2, −5) ⇝ ψ(u) =
+(u − 7)(u − 6)u(u + 1)(u + 7)(u + 8)
+(u − 4)(u − 3)(u − 2)(u + 3)(u + 5)(u + 10)
+(7.57)
+(0, ϵ2, ϵ3)(0, 3, −5) ⇝ ψ(u) =
+(u − 8)(u − 1)u(u + 7)(u + 8)
+(u − 3)(u − 2)(u + 2)(u + 5)(u + 10)
+(7.58)
+Combinatorially, they correspond to adding three boxes to ground state configuration of
+Figure 3. We can put pile of three boxes along first or third directions or an L-shaped
+configuration of boxes in any of the three planes.
+The O(q1) term in expansion of ILW Hamiltonians comes from the matrix element
+between ⟨□| and |□⟩ states in the auxiliary space. As such, these matrix elements are related
+to amplitude of addition and removal of a box in a Young diagram. The product of these
+two amplitudes (which is independent of the normalization of the vectors in representation
+space) is known to be expressible in terms of a residue of the generating function of Yangian
+charges ψ(u), see [27] section 4.4. For this reason, it is not surprising that we have the
+following empirical formula for O(q1) term in the expansion of the Bethe roots around
+q = 0:
+x = x0 − q · resu→x0 ψ(u) + O(q2)
+(7.59)
+– 60 –
+
+where x0 is the q → 0 limit of the given Bethe root. Applying this formula to functions
+in (7.54) exactly reproduces the first order terms in appendix F.1.2. Since ψ(u) only has
+poles at points where a box can be added or removed [27], the Bethe roots corresponding
+to boxes deeper in the Young diagram start at higher orders in q-expansion. We can see
+from explicit calculations such as those given in F.1.2 that the first non-trivial power of q
+(apart from the constant term) is given by (one plus) the number of boxes that need to be
+removed from the Young diagram before the given box becomes removable. All of this is
+consistent with the analysis in appendix D of [61] where Bethe equations are studied to the
+first order in q-expansion.
+7.3
+Numerical tests in first unitary W4 model
+In this section we want to numerically test the formulas (6.44) and (6.48). If we want spin
+4 field U4(z) to be non-trivial, we need to have rank of WN algebra to be at least 4. For
+this reason and for concreteness we choose the first unitary minimal model of W4 algebra.
+The λ-parameters of W∞ are determined by the constraints
+1
+λ1
++ 1
+λ2
++ 1
+λ3
+= 0,
+2
+λ1
++ 1
+λ2
++ 0
+λ3
+= 1,
+λ3 = 4
+(7.60)
+(the middle equation corresponds to the choice of the first unitary minimal model). These
+equations have unique solution
+λ1 = −2
+3,
+λ2 = 4
+5,
+λ3 = 4.
+(7.61)
+The corresponding central charge is
+c∞ = (λ1 − 1)(λ2 − 1)(λ3 − 1) = 1.
+(7.62)
+In general, for the first unitary minimal model of WN algebra we would have
+c∞ = 2(N − 1)
+N + 2 .
+(7.63)
+Next we calculate the Nekrasov-like parameters, imposing the conventional restriction
+ϵ1ϵ2 = −1 that fixes the overall scaling symmetry up to an overall sign. We find
+ϵ1 =
+�
+6
+5,
+ϵ2 = −
+�
+5
+6,
+ϵ3 =
+�
+5
+6 −
+�
+6
+5
+(7.64)
+and
+ψ0 = 4,
+α0 =
+�
+5
+6 −
+�
+6
+5 = − 1
+√
+30.
+(7.65)
+Finally, we restrict to the vacuum representation so the generating function of higher spin
+charges of the ground state is
+A(u) = u + ψ0ϵ1ϵ2ϵ3
+u
+=
+u +
+4
+√
+30
+u
+.
+(7.66)
+– 61 –
+
+With this choice, all ψj, j ≥ 1 vanish. Writing this in terms of Coulomb parameters aj,
+A(u) =
+N
+�
+ℓ=1
+u + aℓ − ϵ3
+u + aℓ
+,
+(7.67)
+we can determine these to be
+a1 = 0,
+a2 =
+1
+√
+30,
+a3 =
+2
+√
+30,
+a4 =
+3
+√
+30.
+(7.68)
+Finally, we want to know how many states there are in the vacuum representation of this
+unitary minimal model. We could either use the general Weyl character formula [44], or
+simply count boxes in staircase configuration as in Figure 4, but with the height of green-
+brown wall being 4 instead of 2 (since we are considering W4 minimal model). The position
+of the pit in the horizontal yellow plane is still the same, because both models are first
+unitary minimal models so have a null state at level 6. Counting the boxes, we find the
+character proportional to
+1 + q + 3q2 + 6q3 + 13q4 + 23q5 + 45q6 + . . .
+(7.69)
+Probably the easiest way to get this is to consider first MacMahon function counting all
+plane partitions. At level 5 we have one less state because we are in W4. At level 6 there are
+three missing states, one of them being prohibited by the existence of the pit and the other
+two states correspond to plane partitions with 6 boxes whose height exceeds 4. In order to
+find number of states in W4 vacuum representation, we need to subtract the contribution
+of Heisenberg algebra and we finally find the state counting function
+1 + q2 + 2q3 + 4q4 + 6q5 + 12q6 + . . .
+(7.70)
+Let us now find the eigenvalues of W3,0 and S4 and match them with solutions of BAE.
+Level 0
+Since formulas (6.44) and (6.48) only give eigenvalues relative to the lowest weight
+state, we first calculate the eigenvalue of W3,0 and S4 on the vacuum state. The first one
+vanishes by parity the second one has eigenvalue
+−
+121
+115200.
+(7.71)
+In the following, we will list the eigenvalues of S4 relative to this value.
+Level 1
+The analysis at level 1 is very simple becase there are no states at this level.
+Level 2
+On level 2 we expect only one physical solution that is regular as q → 1, since
+we have only one state
+L−2 |0⟩ .
+(7.72)
+W3,0 acting on this state is zero by parity, while S4 eigenvalue relative to vacuum is
+− 121
+240 = −0.5041¯6.
+(7.73)
+– 62 –
+
+The physical solution of Bethe equations is
+x1 = −0.807679 . . . ,
+x2 = 0.077382 . . .
+(7.74)
+and formulas (6.44) and (6.48) give us eigenvalues zero and −0.5041¯6 in agreement with
+the explicit calculation.
+Level 3
+Here we expect two states. In the basis L−3 |0⟩ and W3,−3 |0⟩ the matrix of W3,0
+is
+�
+0 4
+5
+6 0
+�
+.
+(7.75)
+The matrix is off-diagonal due to parity. The eigenvalues are
+±
+�
+24
+5 .
+(7.76)
+The matrix of S4 relative to the lowest weight state is
+�
+− 363
+160
+0
+0
+− 363
+160
+�
+(7.77)
+with obvious eigenvalues. These matrices also clearly commute. The corresponding solu-
+tions of BAE are
+(−1.39495, −0.847418, 0.0514826),
+(−0.781779, 0.117121, 0.664658)
+(7.78)
+which using (6.44) and (6.48) give exactly the eigenvalues we want. Note that due to the
+fact that every iteration of Newton’s method doubles the number of digits, we can find the
+Bethe roots with almost arbitrary precision once we have the right initial seed.
+Level 4
+Let us finally look at solutions at level 4. There are 4 states, the parity even
+states
+L−4 |0⟩ ,
+L2
+−2 |0⟩ ,
+W4,−4 |0⟩
+(7.79)
+and one parity odd state
+W3,−4 |0⟩ .
+(7.80)
+The matrix of W3,0 must be block off-diagonal in this basis and it is equal to
+�
+�
+�
+�
+�
+0 0
+0
+64
+45
+0 0
+0
+256
+135
+0 0
+0
+−8
+8 8 − 121
+270
+0
+�
+�
+�
+�
+�
+(7.81)
+with eigenvalues
++ 2
+�
+113
+15 , −2
+�
+113
+15 , 0, 0.
+(7.82)
+– 63 –
+
+The matrix of S4 is block diagonal
+�
+�
+�
+�
+�
+− 121
+24
+− 121
+60
+− 242
+2025
+0
+− 121
+90 − 1331
+360
+3388
+6075
+0
+12
+24
+55
+72
+0
+0
+0
+0
+− 847
+120
+�
+�
+�
+�
+�
+(7.83)
+with eigenvalues
+− 847
+120, −847
+120, 11
+120
+�
+−5 + 6
+√
+31
+�
+, 11
+120
+�
+−5 − 6
+√
+31
+�
+.
+(7.84)
+It is easy to check that the matrices representing W3,0 and S4 commute. The corresponding
+solutions of BAE are
+ξ1 = {−1.69167 ± 0.25460i, −0.861612, 0.0396581}
+(7.85)
+ξ2 = {−0.769955, 0.131316, 0.961369 ± 0.254598i}
+(7.86)
+ξ3 = {−0.756691 ± 0.092167i, 0.0263942 ± 0.0921672i}
+(7.87)
+ξ4 = {−1.41680, −0.817274, 0.0869769, 0.686498}
+(7.88)
+and it is easy to check that these give the right values of W3,0 and S4. Since the vacuum
+representation is self-conjugate, the transformation
+xj(q) �→ ˜xj(q) = −xj(q−1) − ψ0ϵ1ϵ2ϵ3
+(7.89)
+maps (physical) solutions of Bethe equations to solutions of Bethe equations. Since the
+local point q = 1 is also invariant under q → q−1, given any solution of Bethe equations xj
+at q = 1,
+− xj − ψ0ϵ1ϵ2ϵ3
+(7.90)
+is also a solution of Bethe equations at q = 1. In the present situation this transformation
+exchanges ξ1 ↔ ξ2 since they have opposite values of W3,0 charge and keeps ξ3 and ξ4
+invariant. We can use this symmetry to decrease the number of independent BAE and
+Bethe roots to 2 and use this to analytically study the Bethe equations.
+8
+Outlook
+The results of this article are of technical nature, but they can be a starting point or
+ingredients in pursuing various future directions.
+Decoupling of W∞ and combinatorics of W∞ states
+It is very well-known that
+states in lowest weight representations of Heisenberg algebra can be enumerated by Young
+diagrams. The Yangian picture of W1+∞ allows us to enumerate states in lowest weight
+representations of W1+∞ in terms of tuples of Young diagrams, in terms of plane parti-
+tions (possibly with Young diagram asymptotics) or in terms of periodic plane partitions.
+Which of these is realized depends on the choice of the parameters of the algebra (physical
+model) and on the lowest weights (choice of the primary). On the other hand, without the
+– 64 –
+
+Heisenberg factor, there is no known natural way of enumerating the states of W∞ repre-
+sentations. The ILW conserved quantities studied here however seem to offer one solution:
+given any curve in the complex q-plane starting at q = 0 and ending at q = 1 and avoiding
+points where the solutions become ambiguous, we can interpolate from eigenstates of Yan-
+gian conserved quantities at q = 0 to pairs of eigenstates of Heisenberg × W∞ conserved
+quantities at q = 1. A natural choice of such curve would be along the interval (0, 1), but
+since we have seen that there are singular points on the positive real axis, one should go
+either infinitesimally above or below the real axis. At any finite level M there can be no
+accumulation points (because all the equations can be reduced to polynomial equations of
+finite order) so such prescription is well-defined. It would be interesting to understand such
+a map in more detail.
+Behaviour of Bethe roots around special points
+The points q = 0 and q = ∞ are
+associated to Yangian conserved charges. In examples studied here all Bethe roots had nice
+Taylor expansion around these points (and we found nice combinatorial interpretation of
+the first two Taylor series coefficients). It would be nice if there was a nice combinatorial
+way of calculating higher order terms in the expansion. One of the reasons is that at higher
+levels there are continuous families of unphysical solutions of BAE so one needs to go to
+higher orders in Taylor expansion in order to fully specify the initial conditions in order to
+use the monodromy method [53].
+The local behaviour around the point q = 1 as well as around other roots of unity
+is more puzzling. The (twisted) Heisenberg subalgebras decouple at these points and the
+Bethe roots associated to such subalgebras of W1+∞ blow up. But the local behaviour of
+Bethe roots encodes information about these Heisenberg excitations in very subtle way: the
+higher conserved quantities of Heisenberg algebra appear at higher orders in Laurent series
+expansion, but at these orders, the (twisted) Heisenberg Bethe roots interact non-linearly
+with the remaining Bethe roots. It is rather surprising how simple discrete information
+such as the Heisenberg Young diagram is captured by non-linear Bethe equations and how
+it is encoded in the local behaviour of the Bethe roots around these roots of unity.
+Proof of FJMM formula, shuffle algebra
+The main missing step in calculations in
+this article is the fact that we did not attempt to prove the Feigin-Jimbo-Miwa-Mukhin
+formula for the spectrum of Hq(u) (and neither did we prove the associated Bethe ansatz
+equations). What we did was to numerically verify that the first five ILW Hamiltonians
+calculated from the instanton R-matrix have spectrum as predicted by FJMM formula. It
+would be very useful to have algebraic derivation of Bethe ansatz equations along the lines
+of algebraic Bethe ansatz. One problem is that in the usual spin chain one has access to
+ladder operators that commute for any value of the spectral parameter, so it is easy to write
+an off-shell Bethe state parametrized by a collection of spectral parameters, in which it is
+symmetric (as a consequence of the commutativity). The natural ladder operator e(u) that
+we have in W1+∞ however does not commute with itself at different values of u. This seems
+to be an obstruction for following the standard algebraic Bethe ansatz procedure literally.
+On the other hand, the algebra of ladder operators in W1+∞ has beautiful shuffle algebra
+description [60], where all the ladder operators are labeled by symmetric polynomials and
+– 65 –
+
+the associative product of the algebra gets translated to star product remotely reminiscent of
+the Moyal product. It is actually this shuffle algebra picture that is an important ingredient
+of the proof by Feigin-Jimbo-Miwa-Mukhin.
+Map between solutions of different Bethe ansatz equations
+Currently we have at
+our disposal two different looking sets of Bethe ansatz equations, the equations of Gaudin
+type, introduced by Bazhanov, Lukyanov and Zamolodchikov (for Virasoro algebra) and
+the equations of XXX spin chain type (but with higher order scattering amplitude) studied
+by Litvinov. The advantage of Litvinov’s equations is that they are uniform for the whole
+W1+∞, respect the symmetries of the algebra and in addition come with natural monodromy
+parameter that allows their solution using the homotopy method. On the other hand, the
+Gaudin type equations have been studied more thoroughly and there is clear connection
+via ODE/IM correspondence to quantized spectral curves. The KdV conserved charges are
+encoded in WKB expansion of the wave function [62] which is therefore a natural generating
+function of the higher conserved quantities.
+It would be really useful to understand the map between the two pictures. At every
+finite level, we have finite number of Bethe roots and an infinite set of algebraic equations
+connecting them, so one would hope that there should be a natural map relating these.
+In W1+∞ there are two kinds of generating functions (local fields, currents) that one can
+introduce to describe the algebra. From the first point of view, we introduce the generating
+function by summing over Fourier modes and the resulting generating function becomes a
+local field in CFT. The parameter of the generating function is simply the coordinate on the
+CFT worldsheet. A second approach is to sum over the spin label of the W1+∞ generators,
+obtaining Yangian currents. The associated parameter of these generating functions is the
+spectral parameter and lives in the same space where the zero modes of Heisenberg fields
+(or Coulomb parameters) live. The differential operators such as the Miura operator act
+in the CFT space, but Litvinov’s Bethe ansatz equations are in the spectral parameter
+space. On the other hand, the picture of Bazhanov, Lukyanov and Zamolodchikov involves
+a Schrödinger differential operator with monster potential and the Bethe roots live in the
+space where the differential operator acts, the Bethe roots being positions of singularities
+of the potential. It would seem natural to identify the Miura and BLZ operators, since for
+WN algebra they are both N-th order ordinary differential operators. But as argued in [24],
+we should not do so, in particular because for simple Lie algebras which are not Langlands
+self-dual the two operators are related to Langlands dual algebras. If there was a natural
+map between Bethe roots of Litvinov and BLZ Bethe equations, one could understand the
+relation between the two spaces. In the related quantum toroidal setting such relation is
+understood thanks to so-called Miki automorphism [63] which exchanges the mode and spin
+spaces (which is geometrically related to fiber-base duality [64]) and the fact that there can
+be different systems of Bethe ansatz equations associated to the same physical system is an
+example of more general phenomenon called spectral duality [65–68]. There is also a close
+connection to (affine) Gaudin models, starting from [24] and recently discussed for example
+in [69–73].
+– 66 –
+
+Gluings and BPS algebras
+It is an important open question to describe the space
+of vertex operator algebras.
+In [49, 52], a large class of vertex operator algebras was
+constructed with W1+∞ or its truncations YN1N2N3 serving as fundamental building blocks.
+A parallel construction in the Yangian language was studied in [74–78].
+But there are
+other important vertex algebras which seem to require more complicated basic elements
+[45, 79]. One such generalization is to consider the Grassmannian vertex operator algebra
+as a more general building block. Just as W1+∞ is a two-parametric family of algebras,
+the unitary Grassmannian coset algebras depend on three complex parameters. But there
+are indications from the representation theory [79] that these algebras are part of four-
+parametric family of algebras. Performing a OPE bootstrap for Grassmannian analogously
+to [19, 20] is much more difficult due to significantly larger number of local fields, so it would
+be good to find other approaches to study these algebras. Due to their simple structure,
+Bethe ansatz equations seem to be a natural starting point for such generalizations. See
+[80] for recent discussion in the context of BPS algebras associated to quiver gauge theories.
+Hamiltonian structures and KP hierarchy
+On the classical level, many integrable
+systems admit bi-Hamiltonian structure, i.e. two Poisson brackets whose linear combina-
+tions are also Poisson brackets. Kadomtsev-Petviashvili hierarchy is one of such integrable
+systems. W1+∞ discussed here can be thought of as quantized KP hierarchy with respect
+to so-called second Hamiltonian structure. Interestinly, in [81], the authors quantized KP
+equation directly with respect to the first Hamiltonian structure and by directly using the
+coordinate Bethe ansatz obtained the same Bethe ansatz equations as those considered
+here. It would be really interesting to understand how to relate the different Hamiltonian
+structures at quantum level.
+Thermodynamics and modular properties of the higher local charges
+There is
+a very nice interplay between low energy and high energy properties of two-dimensional
+conformal field theories.
+In particular, studying CFT on a torus for different values of
+the modular parameter lead Cardy [82] to a formula which relates the counting of highly-
+excited states to low energy properties of the system. On mathematics side, this manifests
+by the fact that characters of irreducible representations of vertex operator algebras often
+transform nicely under modular transformations.
+We can refine this IR/UV duality by introducing various probes in our system, the
+simplest being an integral of local fields such as (TT)(z) along a spatial circle (for a nice
+recent discussion see [83, 84]). Since (TT)(z) is quasi-primary, it transforms nicey under
+conformal transformations (in fact it transforms under global conformal transformations of
+Riemann sphere in the same way as primary fields), so naïvely we would expect nice modular
+properties of torus partiton functions with insertions of higher spin charges such as (TT)0.
+The problem is that in order to calculate the cylinder zero mode, we need to integrate
+along the spatial cycle and this is in turn mapped to a temporal cycle under modular S-
+transformation. A clever idea of Dijkgraaf [85] is to use the translation-invariance along
+the time direction on the torus to average the expectation value of (TT)0, extending the
+integral along the cycle to an integral over the whole torus. After doing this, the integration
+region is invariant under modular transformations so the characters refined by insertions
+– 67 –
+
+of operators such as (TT)0 still transform nicely under modular transformations. Once we
+insert more such operators, the argument has to be refined, because the local operators can
+have singularities at coincident points and a regularization is needed to resolve that, leading
+to modular anomalies that are correlated to operator product expansions of the local fields
+whose zero modes we are inserting.
+The higher spin extensions have not received so much attention (but see [86–88] for
+recent discussion), so it would be very interesting to understand the interplay of modularity
+with higher spin symmetries of W1+∞ more thoroughly. We saw many (quasi-)modular
+forms appearing in expansions of various ILW quantities. The construction of conserved
+quantities from R-matrix by algebraic Bethe ansatz introduces an auxiliary torus. If we keep
+the quantum space to be on a cylinder, there is no reason to expect modular invariance to be
+there. From the explicit calculations, we saw that the matrix elements of ILW Hamiltonians
+were rational functions of q, all of the Eisenstein series could be eliminated by redefinition of
+Hamiltonians. Also the Bethe equations have purely rational form. The situation changes
+when we put the quantum space on a torus as well. The configuration becomes symmetric
+and the infinite sum of matrix elements of ILW Hamiltonians have similar form to Eisenstein
+series and we can ask if there are any transformations acting on both tori that would be
+symmetries of the setup. One would need to understand the interaction between combined
+modular transformations acting in certain way on both tori and the insertion of R-matrix
+coupling both tori.
+The thermodynamic properties enter the game also if we want to understand the local
+limit of ILW Hamiltonians. The Yangian limit, q → 0, corresponds to low temperatures
+in the auxiliary torus, where the lowest energy states dominante the trace. In this limit,
+the Bethe roots of the quantum space are frozen to their Yangian positions, which can be
+described using combinatorics of plane partitions. As we increase q, the excited states in the
+auxiliary torus contribute as well. In the local limit q → 1 we are removing the regulator,
+so the highly excited states should dominate. The typical Young diagram converges to a
+limit shape and it is the geometry of this limit shape that should control the Hamiltonians
+in the local limit.
+Elliptic Calogero model
+To simplify the calculations, we could try to choose a simpler
+auxiliary space. In particular, there are representations of the algebra where the generators
+of algebra act as quantum mechanical differential operators such in Calogero systems where
+finite number of particles in one direction interact with 1/r3 forces when particles are close
+to each other.
+The Miura operator can be thought of as a representation of universal
+R-matrix with one of the spaces being the space of functions of z variable on which the
+derivatives act [39, 89]. Applying the algebraic Bethe ansatz but with Calogero space being
+the auxiliary space could lead to simpler expressions for ILW Hamiltonians.
+The transition from Calogero systems to 2d conformal theory is the second quantization,
+where the collective coordinates correspond to Fourier modes of CFT fields.
+The total
+momentum of the system (which is quantized with integer steps) becomes CFT L0 operator
+(which has the same level spacing) and the usual Calogero Hamiltonian corresponds to
+spin 3 conserved quantity in CFT. It would be nice if Litvinov’s Bethe ansatz equations
+– 68 –
+
+applied also to the finite dimensional system before the second quantization. Nekrasov and
+Shatashvili [28] found equations that describe the spectrum of elliptic Calogero model, but
+their equations take the form of thermodynamic limit of Litvinov’s equations. Taking the
+thermodynamic limit to go from a system of finite number of particles to a system with
+infinite number of particles seems to be very natural, but it is less clear what is the rôle
+of thermodynamic limit used to parametrize the solution of elliptic Calogero model which
+has finite number of particles. There are also elliptic Bethe ansatz equations by Felder and
+Varchenko [90] which could again be spectral dual of rational ILW equations studied here.
+It would be very interesting to see how these results about elliptic Calogero model fit in
+the picture discussed here.
+Acknowledgements
+We would like to thank to Lorenz Eberhardt, Matěj Kudrna, Andrew Linshaw, Alexey
+Litvinov, Alex Maloney, Go Noshita, Paolo Rossi, Paolo Rossi, Martin Schnabl, Alessandro
+Sfondrini, Bogdan Stefański, Yuji Tachikawa, Alessandro Torrielli, Petr Vaško, Miroslav
+Veľk and especially to Yutaka Matsuo for useful discussions. The research was supported
+by the Grant Agency of the Czech Republic under the grant EXPRO 20-25775X. The
+research was partially supported by Grant-in-Aid MEXT/JSPS KAKENHI 18K03610. AW
+also wants to thank the FMSP program, JSPS Fellowship, and JSR Fellowship for their
+financial support.
+A
+Fourier expansions and conformal normal ordering
+Here we will compare the conformal normal ordering on the complex plane as well as on
+the cylinder in terms of the corresponding Fourier modes.
+A.1
+Complex plane
+We will start with the case of complex plane which is usually discussed in the textbooks
+[91]. See also the summary in [20]. A field A(z) (for simplicity of notation we consider
+holomorphic fields) of conformal dimension h has Fourier expansion
+A(pl)(z) =
+�
+m∈Z
+z−m−hA(pl)
+m .
+(A.1)
+There are two basic operations that produce more complicated fields – the derivative and
+the normal ordered product of fields.
+Derivatives
+In terms of their Fourier modes, the derivative ∂A has modes related to
+those of A via
+(∂A(pl))n = −(h + n)A(pl)
+n
+(A.2)
+as can be easily seen by taking the derivative of Fourier expansion of A.
+– 69 –
+
+Normal ordering in terms of Fourier modes
+The normal ordered product is slightly
+more complicated. By definition, the (conformal) normal ordered product (AB) of (bosonic)
+local fields A and B is defined by
+(AB)(pl)(w) =
+1
+2πi
+�
+w
+dz
+z − wA(pl)(z)B(pl)(w)
+(A.3)
+=
+1
+2πi
+�
+|z|>|w|
+dz
+z − wA(pl)(z)B(pl)(w) −
+1
+2πi
+�
+|z|<|w|
+dz
+z − wB(pl)(w)A(pl)(z)
+where the fields are implicitly radially ordered. Using the identities
+1
+2πi
+�
+|z|>|w|
+dz
+z − wz−n =
+�
+0
+n > 0
+w−n
+n ≤ 0
+(A.4)
+and
+1
+2πi
+�
+|z|<|w|
+dz
+z − wz−n =
+�
+−w−n
+n > 0
+0
+n ≤ 0
+(A.5)
+we find the Fourier expansion of (AB) to be of the form
+(AB)(pl)(w) =
+�
+k
+w−hA−hB−k(AB)(pl)
+k
+(A.6)
+with
+(AB)(pl)
+n
+=
+�
+k≤−hA
+A(pl)
+k
+B(pl)
+n−k +
+�
+k>−hA
+B(pl)
+n−kA(pl)
+k
+(A.7)
+which expresses the Fourier modes of the composite field (AB) in terms of those of A and
+B. If A and B were anticommuting, there will be an additional minus sign every time the
+order of A and B is exchanged.
+Commutators of Fourier modes
+It is useful to derive the relation between the commu-
+tator of Fourier modes of two local fields A and B and their operator product expansion.
+Given two local fields A and B of dimensions hA and hB, their Fourier modes can be
+extracted by contour integral
+A(pl)
+m
+=
+�
+0
+dz
+2πiA(pl)(z)zm+hA−1
+(A.8)
+and similarly for B. We can compute the commutation relations between the modes as
+�
+A(pl)
+m , B(pl)
+n
+�
+=
+�
+0
+dw
+2πi
+�
+|z|>|w|
+dz
+2πizm+hA−1wn+hB−1A(pl)(z)B(pl)(w)
+−
+�
+0
+dw
+2πi
+�
+|z|<|w|
+dz
+2πizm+hA−1wn+hB−1B(pl)(w)A(pl)(z)
+=
+�
+0
+dw
+2πi
+�
+w
+dz
+2πizm+hA−1wn+hB−1A(pl)(z)B(pl)(w)
+(A.9)
+=
+�
+k>0
+�m + hA − 1
+k − 1
+�
+{AB}(pl)
+−k,m+n
+– 70 –
+
+In the second equality we performed the standard contour deformation, deforming the
+difference of two pairs of contours into a w-contour around w = 0 and z-contour around
+z = w. On the right-hand side the notation {AB}(pl)
+−k,m+n means the m + n-th Fourier
+mode of the local operator that appears as k-th order pole in OPE of A and B. Let us
+emphasize that the expression that we derived shows that all the commutation relations
+between Fourier modes of local operators are determined solely from the singular part of
+the operator product expansion of the two operators.
+A.2
+Cylinder
+Let us repeat the previous calculations, this time on the cylinder, i.e. in coordinate y related
+to the plane coordinate z by the exponential map,
+z = ey.
+(A.10)
+Note that for simplicity we do not introduce any signs or imaginary units so in particular
+the circles around origin in the complex plane are mapped to at line segments with constant
+real part and imaginary part running over an interval of length 2π.
+The Fourier expansion of a local field A on the cylinder is now
+A(cyl)(y) =
+�
+m∈Z
+e−myA(cyl)
+m
+.
+(A.11)
+In general these Fourier modes are not equal to those calculated in the complex plane,
+A(cyl)
+m
+̸= A(pl)
+m .
+(in general)
+(A.12)
+Conformal primary fields
+One exception is a conformal primary field A(z) of conformal
+dimension h which by definition transforms as
+A(z)(z)dzh = A(w)(w)dwh
+(A.13)
+under conformal transformation z = z(w). Specializing to the exponential map between
+the complex plane and cylinder (A.10), this gives
+A(pl)(z)zh = A(cyl)(y)
+(A.14)
+so in this case we indeed have A(cyl)
+m
+= A(pl)
+m
+(actually this relation is the reason why Fourier
+modes in (A.1) are conventionally shifted by h). But already the stress-energy tensor T(z)
+has more complicated transformation property than (A.13) which is responsible for the
+shift between the zero mode of T on the complex plane and the zero mode on the cylinder
+(the difference after adding the holomorphic and anti-holomorphic contributions being the
+Casimir energy).
+Derivatives
+The Fourier modes of field A and its derivative ∂A are very simply related:
+(∂A(cyl))m = −mA(cyl)
+m
+.
+(A.15)
+In particular, a zero mode of a total derivative vanishes (which was not true in the case of
+complex plane).
+– 71 –
+
+Normal ordering in terms of Fourier modes
+In order to express the (conformal)
+normal ordering in terms of Fourier modes on cylinder, we first invert the Fourier expansion
+of A:
+A(cyl)
+m
+=
+1
+2πi
+� 2πi
+0
+emyA(cyl)(y)dy = 1
+2π
+� 2π
+0
+eimt+mrA(cyl)(r + it)dt
+(A.16)
+where in the first integral we integrate over a segment of length 2π parallel to the imaginary
+axis, i.e. y = it + r, t ∈ (0, 2π), r = const. The conformal normal ordered product of fields
+on the cylinder is calculated as (assuming A and B to be bosonic)
+(A(cyl)B(cyl))(cyl)(x) =
+1
+2πi
+�
+x
+dy
+y − xA(cyl)(y)B(cyl)(x)
+=
+1
+2πi
+�
+x
+dy
+ey−x − 1A(cyl)(y)B(cyl)(x)
+−
+∞
+�
+k=1
+�
+x
+Bk
+k! (y − x)k−1A(cyl)(y)B(cyl)(x)
+(A.17)
+=
+1
+2πi
+�
+x
+dy
+ey−x − 1A(cyl)(y)B(cyl)(x) −
+�
+k>0
+Bk
+k!
+�
+A(cyl)B(cyl)�
+−k (x)
+In order to be able to apply the contour deformation argument, we need the integrand to
+be a function globally defined on the cylinder (i.e. 2π-periodic in the imaginary direction).
+For this reason, in the second equality we replaced a non-periodic function (y − x)−1 by its
+periodic version up to a correction that is expressible in terms of singular part of OPE of
+A and B. Here Bk are the Bernoulli numbers (B1 = − 1
+2, B2 = 1
+6, B3 = 0, B4 = − 1
+30, . . .).
+The fields are implicitly radially ordered (which in this case means that the field A(x) with
+ℜx > ℜy appears to the left of B(y) etc.).
+We can now use the contour deformation argument to write the first term as
+1
+2πi
+��
+ℜy>ℜx
+−
+�
+ℜy<ℜx
+�
+dy
+ey−x − 1A(cyl)(y)B(cyl)(x)
+(A.18)
+The integral is along the line segment of constant real part. Plugging in the mode expan-
+sions, its remains to evaluate the integrals
+�
+ℜy>ℜx
+e−mye−nx
+ey−x − 1
+dy
+2πi =
+�
+0
+m ≥ 0
+e−(m+n)x
+m ≤ −1
+(A.19)
+�
+ℜy<ℜx
+e−mye−nx
+ey−x − 1
+dy
+2πi =
+�
+−e−(m+n)x
+m ≥ 0
+0
+m ≤ −1
+(A.20)
+where we are integrating along a y-contour which is a segment of length 2π parallel with
+imaginary axis. Finally, we find the normal ordered product in terms of Fourier modes on
+cylinder,
+(A(cyl)B(cyl))(cyl)(x) =
+�
+n∈Z
+�
+m<0
+e−(m+n)xAmBn +
+�
+n∈Z
+�
+m≥0
+e−(m+n)xBnAm
+– 72 –
+
+−
+�
+k>0
+Bk
+k!
+�
+A(cyl), B(cyl)�
+−k (x)
+(A.21)
+or
+(AB)(cyl)
+m
+=
+�
+n<0
+A(cyl)
+n
+Bm−n +
+�
+n≥0
+Bm−nAn −
+�
+k>0
+Bk
+k! {AB}(cyl)
+−k,m .
+(A.22)
+We see that unlike for the Fourier modes on the complex plane, here the normal order
+depends on the singular part of the OPE of A and B.
+Just as for the complex plane,
+anticommuting fields would have an additional minus sign in the second term.
+Commutators of Fourier modes
+Finally we derive the expression for commutator of
+Fourier modes in terms of singular part of operator product expansion. We have
+�
+A(cyl)
+m
+, B(cyl)
+n
+�
+=
+1
+(2πi)2
+���
+ℜy>ℜx
+−
+��
+ℜx>ℜy
+�
+enx+myA(cyl)(y)B(cyl)(x)
+=
+� 2πi
+0
+dx
+2πi
+�
+x
+dy
+2πienx+myA(cyl)(y)B(cyl)(x)
+=
+� 2πi
+0
+dx
+2πi
+�
+x
+dy
+2πi
+�
+k>0
+enx+my
+(y − x)k
+�
+A(cyl)B(cyl)�
+−k (x)
+(A.23)
+=
+� 2πi
+0
+dx
+2πi
+�
+k>0
+e(m+n)xmk−1
+(k − 1)!
+�
+A(cyl)B(cyl)�
+−k (x)
+=
+�
+k>0
+mk−1
+(k − 1)!
+�
+A(cyl)B(cyl)�
+−k,m+n
+In particular, for m = 0 only the first order pole (k = 1) contributes and we have a simple
+relation
+�
+A(cyl)
+0
+, B(cyl)(x)
+�
+=
+�
+A(cyl)B(cyl)�
+−1 (x).
+(A.24)
+An analogous commutator of a zero mode on the plane is more complicated and involves
+all of the singular terms of OPE.
+A.3
+Example - Virasoro algebra
+The stress-energy tensor T(z) has the following operator product expansion with respect
+to any choice of complex coordinates
+T(z)T(w) =
+c/2
+(z − w)4 +
+2T(w)
+(z − w)2 + ∂T(w)
+z − w + reg.
+(A.25)
+Denoting the Fourier modes of T(z) in complex plane by Lm, we can use (A.9) to find the
+commutator
+[Lm, Ln] =
+�m + 1
+3
+�c
+21m+n +
+�m + 1
+1
+�
+2Lm+n +
+�m + 1
+0
+�
+(−m − n − 2)Lm+n
+= c(m + 1)m(m − 1)
+12
+δm+n,0 + (m − n)Lm+n
+(A.26)
+– 73 –
+
+which is the Virasoro algebra. Denoting the corresponding Fourier modes on the cylinder
+by Tm, the commutation relations of these are instead
+[Tm, Tn] = m3
+6
+c
+21m+n + 2mTm+n − (m + n)Tm+n
+= cm3
+12 δm+n,0 + (m − n)Tm+n
+(A.27)
+as follows from (A.23). This is the Virasoro algebra on the cylinder. The two commutation
+relations are related by the identification
+Tm = Lm − c
+24δm,0
+(A.28)
+which is a consequence of the transformation property of stress-energy tensor under con-
+formal transformations
+� dz
+dw
+�2
+T (z)(z) = T (w)(w) − c
+12
+�� d3z
+dw3
+� � dz
+dw
+�−1
+− 3
+2
+� d2z
+dw2
+�2 � dz
+dw
+�−2�
+.
+(A.29)
+which in the case of exponential map (A.10) simplifies to
+z2T (cyl)(z) = T (pl)(y) + c
+24.
+(A.30)
+To check the expression for Fourier modes of composite fields, let us consider the zero
+mode of a local operator (TT)(x) on the cylinder. Using (A.22) we find
+(TT)(cyl)
+0
+= T 2
+0 + 2
+�
+m>0
+T−mTm +
+1
+720
+c
+2 − 1
+122T0 + 1
+2(∂T)0
+= T 2
+0 + 2
+�
+m>0
+T−mTm +
+c
+1440 − 1
+6T0
+(A.31)
+= L2
+0 + 2
+�
+m>0
+L−mLm − c + 2
+12 L0 + c(5c + 22)
+2880
+which agrees with expressions given in appendix of [3].
+As a side comment, observe that the constant term vanishes for c = − 22
+5 which is the
+Lee-Yang minimal model (related to (A1, A2) Argyres-Douglas theory) and for this value
+of central charge (TT)(cyl)
+0
+vanishes on the primary state if and only if h = 0 and h = − 1
+5
+which are exactly the two primaries of the Lee-Yang minimal model.
+B
+Large u expansion of R-matrix
+B.1
+Mode expansions
+Using the results of appendix A, we can find the cylinder Fourier modes of the composite
+operators constructed out of local current J− with OPE
+J−(z)J−(w) ∼
+2α2
+0
+(z − w)2 + reg.
+(B.1)
+– 74 –
+
+that enters the large central charge expansion of the instanton R-matrix. We find using
+(A.22)
+(J−J−)m =: J2
+− :m −2α2
+0
+12 δm,0
+(B.2)
+(J−(J−J−))m =: J3
+− :m −2α2
+0
+4
+: J− :m
+(B.3)
+(J−(J−(J−J−)))m =: J4
+− :m −2α2
+0
+2
+: J2
+− :m +4α4
+0
+48 δm,0
+(B.4)
+(∂J−∂J−)m =: ∂J−∂J− :m −2α2
+0
+120δm,0
+(B.5)
+where : Jk
+− : denotes the creation-annihilation normal ordering and we suppress the subscript
+(cyl) associated to Fourier modes on the left-hand side.
+B.2
+Large u expansion of R at N = 1
+Here we collect expressions for first coefficients r(j) of the large u expansion of the logarithm
+of Maulik-Okounkov R-matrix. First five of these were given in [39] in terms of oscillators.
+Here we write them as zero modes of local currents. In this appendix we write J instead of
+J− to simplify the notation. All zero modes are with respect to coordinates on the cylinder.
+r(1) = −1
+2(JJ)0
+(B.6)
+r(2) = 1
+6(J(JJ))0
+(B.7)
+r(3) = − 1
+12(J(J(JJ)))0 + α2
+0(1 + 2α2
+0)
+12
+(∂J∂J)0
+(B.8)
+r(4) = 1
+20(J(J(J(JJ))))0 − α2
+0(1 + 2α2
+0)
+4
+(∂J(∂JJ))0
+(B.9)
+r(5) = − 1
+30(J(J(J(J(JJ)))))0 + α2
+0(1 + 2α2
+0)
+2
+(∂J(∂J(JJ)))0
+− α4
+0(2 + 9α2
+0 + 6α4
+0)
+60
+(∂2J∂2J)0
+(B.10)
+r(6) = 1
+42(J(J(J(J(J(JJ))))))0 − 5α2
+0(1 + 2α2
+0)
+6
+(∂J(∂J(J(JJ))))0
++ α4
+0(2 + 9α2
+0 + 6α4
+0)
+12
+(∂2J(∂2JJ))0
+(B.11)
+r(7) = − 1
+56(J(J(J(J(J(J(JJ)))))))0 + 5α2
+0(1 + 2α2
+0)
+4
+(∂J(∂J(J(J(JJ)))))0
+− α4
+0(2 + 9α2
+0 + 6α4
+0)
+4
+(∂2J(∂2J(JJ)))0 + α4
+0(9 + 41α2
+0 + 26α4
+0)
+72
+(∂J(∂J(∂J∂J)))0
++ α6
+0(90 + 671α2
+0 + 998α4
+0 + 360α6
+0)
+5040
+(∂3J∂3J)0
+(B.12)
+r(8) = 1
+72(J(J(J(J(J(J(J(JJ))))))))0 − 7α2
+0(1 + 2α2
+0)
+4
+(∂J(∂J(J(J(J(JJ))))))0
++ 7α4
+0(2 + 9α2
+0 + 6α4
+0)
+12
+(∂2J(∂2J(J(JJ))))0
+– 75 –
+
+− 7α4
+0(9 + 41α2
+0 + 26α4
+0)
+72
+(∂J(∂J(∂J(∂JJ))))0
+(B.13)
+− α6
+0(90 + 671α2
+0 + 998α4
+0 + 360α6
+0)
+720
+(∂3J(∂3JJ))0
++ α6
+0(25 + 186α2
+0 + 278α4
+0 + 100α6
+0)
+180
+(∂2J(∂2J(∂2J)))0
+B.3
+Large u expansion of universal R
+In this appendix we list expressions of coefficients r(j) of the large central charge expansion
+of the logarithm of R(u), see (3.5). We have
+r(1) = −α0 ¯NT0 − α0N ¯T0 + α0(U1 ¯U1)0
+(B.14)
+r(2) = α0 ¯N
+2
+φ3,0 − α0(T ¯U1)0 + α0(U1 ¯T)0 − α0N
+2
+¯φ3,0
+(B.15)
+r(3) = α0 ¯N
+3
+φ4,0 + α0(φ3 ¯U1)0 − 2α0(T ¯T)0 + α0(U1 ¯φ3)0 + Nα0
+3
+¯φ4,0
++
+¯N( ¯N − 1)α3
+0
+12
+(∂U1∂U1)0 + N(N − 1)α3
+0
+12
+(∂ ¯U1∂ ¯U1)0
+(B.16)
+− 1
+6α0(α2
+0N ¯N − α2
+0N − α2
+0 ¯N − α2
+0 − 1)(∂U1∂ ¯U1)0
+r(4) = α0 ¯N
+4
+φ5,0 + α0( ¯U1φ4)0 + 3α0(φ3 ¯T)0 − 3α0(T ¯φ3)0 − α0(U1 ¯φ4)0 − α0N
+4
+¯φ5,0
+− (N ¯Nα2
+0 − 2 ¯Nα2
+0 − Nα2
+0 − 2α2
+0 − 2)α0
+4
+( ¯U1∂2T)0 − ( ¯N − 1)α3
+0
+4
+( ¯U1(∂2U1U1))0
++ (N ¯Nα2
+0 − 2Nα2
+0 − ¯Nα2
+0 − 2α2
+0 − 2)α0
+4
+(U1∂2 ¯T)0 + (N − 1)α3
+0
+4
+(U1(∂2 ¯U1 ¯U1))0 (B.17)
+− N(N − 1)α3
+0
+4
+( ¯U1∂2 ¯T)0 +
+¯N( ¯N − 1)α3
+0
+4
+(U1∂2T)0
+and more complicated expressions for higher orders. We defined the local fields
+T = −U2 + 1
+2(U1U1) + (N − 1)α0
+2
+∂U1
+(B.18)
+φ3 = U3 − (U1U2) + 1
+3(U1(U1U1)) − (N − 2)α0
+2
+U ′
+2
++ (N − 1)α0
+2
+(U ′
+1U1) + N2α2
+0 − Nα2
+0 + 4α2
+0 + 2
+12
+U ′′
+1
+(B.19)
+φ4 = U4 − (U1U3) − 1
+2(U2U2) + (U1(U1U2)) − 1
+4(U1(U1(U1U1)))
++ (N − 2)α0
+2
+(U1U ′
+2) + (N − 1)α0
+2
+(U ′
+1U2) − (N − 1)α0
+2
+(U ′
+1(U1U1))
+− (N − 3)α0
+2
+U ′
+3 − N2α2
+0 + 2Nα2
+0 + 3α2
+0 + 3
+12
+(U ′
+1U ′
+1)
+(B.20)
+− N2α2
+0 − Nα2
+0 + 12α2
+0 − 3N + 9
+12
+(U ′′
+1 U1) + N2α2
+0 − 3Nα2
+0 + 12α2
+0 + 3
+12
+U ′′
+2
+− (N − 1)(2Nα2
+0 + 6α2
+0 − 2N + 5)α0
+24
+U ′′′
+1
+φ5 = U5 − (U1U4) − (U2U3) + (U1(U1U3)) + (U1(U2U2)) − (U1(U1(U1U2)))
+– 76 –
+
++ 1
+5(U1(U1(U1(U1U1)))) − (N − 2)α0
+2
+(U1(U1U ′
+2)) − (N − 1)α0(U ′
+1(U1U2))
++ (N − 3)α0
+2
+(U1U ′
+3) + (N − 1)α0
+2
+(U ′
+1U3) + (N − 1)α0
+2
+(U ′
+1(U1(U1U1)))
++ (N − 2)α0
+2
+(U ′
+2U2) − (N − 4)α0
+2
+U ′
+4 − N2α2
+0 − 3Nα2
+0 + 22α2
+0 + 6
+12
+(U1U ′′
+2 )
++ N2α2
+0 + 3Nα2
+0 + 8α2
+0 + 6
+6
+(U ′
+1(U ′
+1U1)) − N2α2
+0 + 2Nα2
+0 + 6α2
+0 + 6
+6
+(U ′
+1U ′
+2)
+(B.21)
+− N2α2
+0 − Nα2
+0 + 26α2
+0 − 6N + 24
+12
+(U ′′
+1 U2) + (N − 1)(3Nα2
+0 + 8α2
+0 + 6)α0
+6
+(U ′′
+1 U ′
+1)
++ N2α2
+0 − Nα2
+0 + 24α2
+0 − 6N + 18
+12
+(U ′′
+1 (U1U1)) + N2α2
+0 − 5Nα2
+0 + 24α2
+0 + 6
+12
+U ′′
+3
++ (N − 1)(Nα2
+0 + 8α2
+0 − N + 3)α0
+12
+(U ′′′
+1 U1) − (N − 2)(Nα2
+0 + 6α2
+0 + 4)α0
+12
+U ′′′
+2
+− N4α4
+0 − 16N3α4
+0 − 19N2α4
+0 + 34Nα4
+0 − 144α4
+0 − 15N3α2
+0 + 5Nα2
+0 − 206α2
+0 − 48
+720
+U (4)
+1
+C
+Explicit expressions for ILW Hamiltonians
+C.1
+(Quasi-)modular forms
+First few Eisenstein series are
+E2(q) = 1 − 24
+�
+m>0
+mqm
+1 − qm
+(C.1)
+E4(q) = 1 + 240
+�
+m>0
+m3qm
+1 − qm
+(C.2)
+E6(q) = 1 − 504
+�
+m>0
+m5qm
+1 − qm
+(C.3)
+E8(q) = 1 + 480
+�
+m>0
+m7qm
+1 − qm = E4(q)2
+(C.4)
+and satisfy useful relations
+q∂qE2 = −E4 − E2
+2
+12
+= −24
+�
+m>0
+m2qm
+(1 − qm)2
+(C.5)
+q∂qE4 = −4E6 − E2E4
+12
+= 240
+�
+m>0
+m4qm
+(1 − qm)2
+(C.6)
+q∂qE6 = −6E8 − E2E6
+12
+.
+(C.7)
+All Eistenstein series E2k with 2k ≥ 8 are algebraically dependent on the basic ones E2, E4
+and E6.
+E2 is not modular but only quasi-modular and the ring of modular forms is
+generated by E4 and E6 only. Allowing differentiation q∂q as well, we see that everything
+can be expressed in terms of E2 only.
+– 77 –
+
+C.2
+Calculation of expectation values in auxiliary space
+In order to find explicit formulas for ILW Hamiltonians from the universal R-matrix, we
+need to take torus expectation values of various quantities in the bosonic Fock space. Here
+we list various expectation values of these. We start with two simple lemmas:
+Lemma 1
+⟨O ¯T0⟩q =
+�
+q∂q − E2
+24
+�
+⟨O⟩q
+(C.8)
+⟨O ¯T0⟩qc = q∂q⟨O⟩q
+(C.9)
+Proof: for the first equation, we have
+⟨O¯L0⟩q = q∂q
+�
+λ q|λ| ⟨¯λ| O |¯λ⟩
+�
+λ q|λ|
+= q∂q
+��
+λ q|λ| ⟨¯λ| O |¯λ⟩
+�
+λ q|λ|
+�
++
+�
+λ q|λ| ⟨¯λ| O |¯λ⟩
+�
+λ q|λ|
+q∂q
+�
+λ q|λ|
+�
+λ q|λ|
+(C.10)
+=
+�
+q∂q + 1 − E2
+24
+�
+⟨O⟩q.
+Therefore,
+⟨O ¯T0⟩q = ⟨O¯L0⟩q − 1
+24⟨O⟩q =
+�
+q∂q − E2
+24
+�
+⟨O⟩q
+(C.11)
+as we wanted to show. For the second claim, we have simply
+⟨O ¯T0⟩qc ≡ ⟨O ¯T0⟩q − ⟨O⟩q⟨ ¯T0⟩q = q∂q⟨O⟩q
+(C.12)
+Analogously, we have
+⟨ ¯T 2
+0 O⟩c ≡ ⟨ ¯T 2
+0 O⟩ − ⟨ ¯T 2
+0 ⟩⟨O⟩ − 2⟨ ¯T0⟩⟨ ¯T0O⟩ + 2⟨ ¯T0⟩2⟨O⟩
+=
+�
+q ∂
+∂q − E2
+24
+�2
+⟨O⟩ − E4 − E2
+2
+288
+⟨O⟩ + E2
+12
+�
+q ∂
+∂q − E2
+24
+�
+⟨O⟩ + E2
+2
+576⟨O⟩
+=
+�
+q ∂
+∂q
+�2
+⟨O⟩ −
+�
+q ∂
+∂q
+E2
+24
+�
+⟨O⟩ − E2
+12
+�
+q ∂
+∂q
+�
+⟨O⟩ + E2
+2
+576⟨O⟩
+(C.13)
+− E4 − E2
+2
+288
+⟨O⟩ + E2
+12
+�
+q ∂
+∂q − E2
+24
+�
+⟨O⟩ + E2
+2
+576⟨O⟩
+=
+�
+q ∂
+∂q
+�2
+⟨O⟩.
+Lemma 2
+For two local fields A and B in the left sector (independent of ¯J), we have
+⟨(A ¯J)0(B ¯J)0⟩q =
+�
+m>0
+m
+1 − qm A−mBm +
+�
+m>0
+mqm
+1 − qm AmB−m
+(C.14)
+≡
+�
+m>0
+dmA−mBm +
+�
+m>0
+d−mAmB−m
+(C.15)
+– 78 –
+
+where we introduce the derivative
+dm ≡
+m
+1 − qm .
+(C.16)
+Proof: first of all, one can show easily by calculation similar to evaluation of ⟨ ¯T0⟩q that
+⟨ ¯Jm ¯J−m⟩q = q∂q log
+1
+1 − qm =
+m
+1 − qm = −mq−m
+1 − q−m
+(C.17)
+which holds for both positive and negative m. Due to the fact that A and ¯J commute
+(have regular OPE), their normal ordered product is just their product (and the same for
+A ↔ B) so
+⟨(A ¯J)0(B ¯J)0⟩q =
+�
+m∈Z
+A−mBm⟨ ¯Jm ¯J−m⟩q
+(C.18)
+=
+�
+m>0
+m
+1 − qm A−mBm +
+�
+m>0
+mqm
+1 − qm AmB−m
+(C.19)
+as we wanted to show. We can in principle normal order the right-hand side,
+⟨(A ¯J)0(B ¯J)0⟩q =
+�
+m>0
+m
+1 − qm A−mBm +
+�
+m>0
+mqm
+1 − qm B−mAm +
+�
+m>0
+mqm
+1 − qm [Am, B−m]
+(C.20)
+As an application of this formula, we have
+⟨(U1 ¯J)0(U1 ¯J)0⟩q =
+�
+m>0
+m1 + qm
+1 − qm U1,−mU1,m + N
+�
+m>0
+m2qm
+1 − qm .
+(C.21)
+Similarly, we have the following correlators
+⟨ ¯Tm ¯T−m⟩ = m(m2 − E2)
+12(1 − qm)
+(C.22)
+⟨ ¯Jm( ¯J( ¯J ¯J))−m⟩ = −
+mE2
+4(1 − qm)
+(C.23)
+⟨( ¯J( ¯J ¯J))m ¯J−m⟩ = −
+mE2
+4(1 − qm)
+(C.24)
+⟨ ¯Jm ¯Jn ¯T−m−n⟩ =
+mn
+(1 − qm)(1 − qn)
+(C.25)
+⟨ ¯J−m ¯Jm ¯J−n ¯Jn⟩ = mnqm(δmn + qn)
+(1 − qm)(1 − qn) ,
+m, n > 0
+(C.26)
+which lead to analogous formulas as in lemma 2.
+Some properties of dm
+The modified derivatives dm satisfy various relations. Their
+derivatives are
+q∂qdm = dmd−m.
+(C.27)
+– 79 –
+
+The difference of these derivatives gives an ordinary derivative,
+dm − d−m = m
+(C.28)
+while their sum
+dm + d−m = m1 + qm
+1 − qm
+(C.29)
+is the integral kernel appearing in ILW equation and interpolates between Benjamin-Ono
+or Yangian limit and Bahanov-Lukyanov-Zamolodchikov or Kadomtsev-Petviashvili limits.
+There are also more complicated identities involving infinite sums such as
+�
+j∈Z
+j̸=0,m
+djdm−j = m2 − E2
+6
+dm.
+(C.30)
+C.3
+List of expectation values in auxiliary space
+Here is a list of useful expectation values.
+⟨ ¯T0⟩q = −E2
+24
+(C.31)
+⟨ ¯T 2
+0 ⟩qc = E4 − E2
+2
+288
+(C.32)
+⟨ ¯T 3
+0 ⟩qc = −2E6 + 3E2E4 − E3
+2
+1728
+(C.33)
+⟨ ¯T 4
+0 ⟩qc = 3E2
+4 − 8E2E6 + 6E2
+2E4 − E4
+2
+6912
+(C.34)
+⟨(∂ ¯J∂ ¯J)0⟩q = − 1
+120 − 2
+�
+m>0
+m3qm
+1 − qm = − E4
+120
+(C.35)
+⟨( ¯J( ¯J( ¯J ¯J)))0⟩q = E2
+2
+48
+(C.36)
+⟨( ¯J( ¯J ¯J))0( ¯J( ¯J ¯J))0⟩ = −2E6 − 3E2E4 + 5E3
+2
+720
+(C.37)
+⟨( ¯J( ¯J( ¯J ¯J)))0 ¯T0⟩c = −E2E4 + E3
+2
+288
+(C.38)
+⟨(∂ ¯J∂ ¯J)0 ¯T0⟩c = E6 − E2E4
+360
+(C.39)
+C.4
+Third order ILW Hamiltonian
+We need the following expectation values:
+⟨r(3)⟩ = α0
+3 φ4,0 − 2α0T0⟨ ¯T0⟩ + Nα0
+3
+⟨¯φ4,0⟩ + N(N − 1)α3
+0
+12
+(∂ ¯J∂ ¯J)0
+= α0
+3 φ4,0 + α0E2
+12 T0 − Nα0E2
+2
+576
+− Nα0(1 + α2
+0 + Nα2
+0)E4
+1440
+(C.40)
+⟨r(1)r(2)⟩sc ≡ 1
+2⟨r(1)r(2)⟩ + 1
+2⟨r(2)r(1)⟩ − 1
+2⟨r(1)⟩⟨r(2)⟩ + 1
+2⟨r(2)⟩⟨r(1)⟩
+= −α2
+0NU1,0⟨ ¯T 2
+0 ⟩c − α2
+0
+2 ⟨(U1 ¯J)0(T ¯J)0⟩c − α2
+0
+2 ⟨(T ¯J)0(U1 ¯J)0⟩c
+– 80 –
+
+= −α2
+0NU1,0
+E4 − E2
+2
+288
+− α2
+0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mTm + T−mU1,m)
+− α2
+0
+�
+m>0
+m2qm
+1 − qm U1,0
+(C.41)
+1
+6⟨r(1)3⟩sc ≡ 1
+6⟨r(1)3⟩ − 1
+4⟨r(1)2⟩⟨r(1)⟩ − 1
+4⟨r(1)⟩⟨r(1)2⟩ + 1
+3⟨r(1)⟩3
+= −α3
+0N3
+6
+⟨ ¯T0 ¯T0 ¯T0⟩c + α3
+0
+12T0⟨(U1 ¯U1)0(U1 ¯U1)0⟩ − α3
+0
+6 ⟨(U1 ¯U1)0T0(U1 ¯U1)0⟩
++ α3
+0
+12⟨(U1 ¯U1)0(U1 ¯U1)0⟩T0 − α3
+0N
+3
+⟨ ¯T0(U1 ¯U1)0(U1 ¯U1)0⟩
+− α3
+0N
+6
+⟨(U1 ¯U1)0 ¯T0(U1 ¯U1)0⟩ + α3
+0N
+2
+⟨ ¯T0⟩⟨(U1 ¯U1)0(U1 ¯U1)0⟩
+= −α3
+0N3
+6
+−2E6 + 3E2E4 − E3
+2
+1728
++ α3
+0
+12⟨(∂U1 ¯U1)0(U1 ¯U1)0⟩
+− α3
+0
+12⟨(U1 ¯U1)0(∂U1 ¯U1)0⟩ − α3
+0N
+2
+⟨ ¯T0(U1 ¯U1)0(U1 ¯U1)0⟩
+(C.42)
++ α3
+0N
+2
+⟨ ¯T0⟩⟨(U1 ¯U1)0(U1 ¯U1)0⟩ + α3
+0N
+6
+⟨(U1 ¯U1)0(∂U1 ¯U1)0⟩
+= −α3
+0N3
+6
+−2E6 + 3E2E4 − E3
+2
+1728
+− α3
+0N
+�
+m>0
+m2qm
+(1 − qm)2 U1,−mU1,m − α3
+0N2
+2
+�
+m>0
+m3qm
+(1 − qm)2
+− α3
+0(N − 1)
+6
+�
+m>0
+m2U1,−mU1,m + α3
+0N(N − 1)
+6
+�
+m>0
+m3qm
+1 − qm
+Adding everything, we finally find
+(log Hq)3 = α0
+3 φ4,0 − α2
+0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mTm + T−mU1,m)
++ α3
+0(N + 2)
+12
+�
+m>0
+m2U1,−mU1,m − α3
+0N
+4
+�
+m>0
+m2(1 + qm)2
+(1 − qm)2
+U1,−mU1,m
++ α0E2
+12 T0 − α2
+0N E4 − E2
+2
+288
+U1,0 − α2
+0
+�
+m>0
+m2qm
+1 − qm U1,0
+(C.43)
++ α3
+0N3 2E6 − 3E2E4 + E3
+2
+10368
++ α3
+0N(N − 1)
+6
+�
+m>0
+m3qm
+1 − qm
+− α3
+0N2
+2
+�
+m>0
+m3qm
+(1 − qm)2 − Nα0(1 + α2
+0 + Nα2
+0)E4
+1440
+− Nα0E2
+2
+576
+C.5
+Fourth order ILW Hamiltonian
+⟨r(4)⟩ = α0
+4 φ5,0 − α0E2
+8
+φ3,0 + α0E2
+2
+192 U1,0 + α0(1 + α2
+0 + Nα2
+0)E4
+480
+U1,0
+(C.44)
+1
+2⟨r(1)r(3)⟩sc = 1
+2
+�
+⟨r(1)r(3)⟩ − ⟨r(1)⟩⟨r(3)⟩ + ⟨r(3)r(1)⟩ − ⟨r(3)⟩⟨r(1)⟩
+�
+(C.45)
+– 81 –
+
+= 2α2
+0N⟨ ¯T 2
+0 ⟩cT0 + α2
+0
+2 ⟨(U1 ¯J)0(φ3 ¯J)0⟩ + α2
+0
+2 ⟨(φ3 ¯J)0(U1 ¯J)0⟩
++ α2
+0
+6 ⟨(U1 ¯J)0(U1( ¯J( ¯J ¯J)))0⟩ + α2
+0
+6 ⟨(U1( ¯J( ¯J ¯J)))0(U1 ¯J)0⟩
++ α2
+0N2
+12
+⟨ ¯T0( ¯J( ¯J( ¯J ¯J)))0⟩c − α2
+0(1 + α2
+0 + Nα2
+0)N2
+12
+⟨ ¯T0(∂ ¯J∂ ¯J)0⟩c
+= α2
+0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mφ3,m + φ3,−mU1,m)
+− α2
+0E2
+12
+�
+m>0
+m(1 + qm)
+1 − qm
+U1,−mU1,m
++ α2
+0N E4 − E2
+2
+144
+T0 + 2α2
+0
+�
+m>0
+m2qm
+1 − qm T0
++ α2
+0
+6 (1 + α2
+0 + Nα2
+0)N
+�
+m>0
+m4qm
+1 − qm − α2
+0NE2
+12
+�
+m>0
+m2qm
+1 − qm
++ α2
+0N2
+3456 (−E2E4 + E3
+2) − α2
+0(1 + α2
+0 + Nα2
+0)N2
+4320
+(E6 − E2E4)
+1
+2⟨r(2)2⟩c = 1
+2⟨r(2)2⟩ − 1
+2⟨r(2)⟩2
+(C.46)
+= +α2
+0
+2 ⟨(T ¯J)0(T ¯J)0⟩ + α2
+0
+2 ⟨(U1 ¯T)0(U1 ¯T)0⟩c + α2
+0N2
+72
+⟨( ¯J( ¯J ¯J))0( ¯J( ¯J ¯J))0⟩
+= +α2
+0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+T−mTm + α2
+0
+�
+m>0
+m2qm
+1 − qm T0
++ α2
+0
+2
+�
+m>0
+m(m2 − E2)(1 + qm)
+12(1 − qm)
+U1,−mU1,m
++ α2
+0N2
+72
+−2E6 − 3E2E4 + 5E3
+2
+720
++ α2
+0N
+2
+�
+m>0
+m2qm(m2 − E2)
+12(1 − qm)
++ α2
+0N(1 + α2
+0 − α2
+0N2)
+24
+�
+m>0
+m4qm
+1 − qm + α2
+0
+2
+E4 − E2
+2
+288
+U 2
+1,0
+1
+2⟨r(1)2r(2)⟩sc =
+�1
+6⟨r(1)2r(2)⟩ − 1
+4⟨r(1)2⟩⟨r(2)⟩ − 1
+4⟨r(1)⟩⟨r(1)r(2)⟩ + 1
+3⟨r(1)⟩2⟨r(2)⟩
+�
++
+�1
+6⟨r(1)r(2)r(1)⟩ − 1
+4⟨r(1)r(2)⟩⟨r(1)⟩ − 1
+4⟨r(1)⟩⟨r(2)r(1)⟩ + 1
+3⟨r(1)⟩⟨r(2)⟩⟨r(1)⟩
+�
++
+�1
+6⟨r(2)r(1)2⟩ − 1
+4⟨r(2)r(1)⟩⟨r(1)⟩ − 1
+4⟨r(2)⟩⟨r(1)2⟩ + 1
+3⟨r(2)⟩⟨r(1)⟩2
+�
+(C.47)
+= −α3
+0
+12
+�
+m>0
+m2(T−mU1,m + U1,−mTm) + α3
+0
+6
+�
+m>0
+m3qm
+1 − qm U1,0
+− α3
+0
+6
+�
+m>0
+m2(U1,−mTm + T−mU1,m) + α3
+0
+3
+�
+m>0
+m3qm
+1 − qm U1,0
++ α3
+0N
+�
+m>0
+m2qm
+(1 − qm)2 (U1,−mTm + T−mU1,m) + α3
+0N
+�
+m>0
+m3qm
+(1 − qm)2 U1,0
+– 82 –
+
++ α3
+0N
+6
+�
+m>0
+m2(U1,−mTm + T−mU1,m) − α3
+0N
+3
+�
+m>0
+m3qm
+1 − qm U1,0
++ α3
+0N2
+2
+−2E6 + 3E2E4 − E3
+2
+1728
+U1,0
++ α3
+0
+12
+�
+m,n>0
+(U1,−mU1,−nU1,m+n + U1,−m−nU1,mU1,n)×
+×
+�mn(2 + 2qm+n + qm + qn)
+(1 − qm)(1 − qn)
++ m(m + n)(2qm + 1 + 2qm+n + q2m+n)
+(1 − qm)(1 − qm+n)
++ n(m + n)(2qn + 1 + 2qm+n + qm+2n)
+(1 − qn)(1 − qm+n)
+�
++ α3
+0U1,0
+�
+m>0
+m2qm
+(1 − qm)2 U1,−mU1,m + α3
+0N
+2
+U1,0
+�
+m>0
+m3qm
+(1 − qm)2
++ α3
+0
+6 U1,0
+�
+m>0
+m2U1,−mU1,m − α3
+0N
+6
+U1,0
+�
+m>0
+m3qm
+1 − qm
+1
+24⟨r(1)4⟩ =
+� 1
+24⟨r(1)4⟩ − 1
+12⟨r(1)3⟩⟨r(1)⟩ − 1
+12⟨r(1)⟩⟨r(1)3⟩ − 1
+8⟨r(1)2⟩2
++ 1
+6⟨r(1)⟩2⟨r(1)2⟩ + 1
+6⟨r(1)⟩⟨r(1)2⟩⟨r(1)⟩ + 1
+6⟨r(1)2⟩⟨r(1)⟩2 − 1
+4⟨r(1)⟩4�
+(C.48)
+= α4
+0
+24
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m − α4
+0N
+6
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m
++ α4
+0N2
+2
+�
+m>0
+m3qm(1 + qm)
+(1 − qm)3
+U1,−mU1,m + α4
+0N2
+24
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m
++ α4
+0N
+24
+�
+m>0
+m4qm
+1 − qm − α4
+0N2
+12
+�
+m>0
+m4qm
+1 − qm + α4
+0N2
+6
+�
+m>0
+m4qm
+(1 − qm)2
++ α4
+0N2
+24
+�
+m>0
+m4qm(1 + 2qm)
+(1 − qm)2
++ α4
+0N3
+24
+�
+m>0
+m4qm
+1 − qm − α4
+0N3
+6
+�
+m>0
+m4qm
+(1 − qm)2
++ α4
+0N3
+4
+�
+m>0
+m4qm(1 + qm)
+(1 − qm)3
++ α4
+0N4
+24
+3E2
+4 − 8E2E6 + 6E2
+2E4 − E4
+2
+6912
+Where we used the following commutation relations:
+[U1,m, φ3,−m] = m3
+6 N(1 + α2
+0 + Nα2
+0) + 2mT0
+(C.49)
+and
+[φ3,0, U1,m] = 2(∂T)m = −2mTm.
+(C.50)
+Adding everything, we find the fourth ILW Hamiltonian
+(log Hq)4 = +α0
+4 φ5,0 + α2
+0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mφ3,m + φ3,−mU1,m)
++ α2
+0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+T−mTm + α3
+0(2N − 3)
+12
+�
+m>0
+m2(U1,−mTm + T−mU1,m)
+– 83 –
+
++ α3
+0N
+�
+m>0
+m2qm
+(1 − qm)2 (U1,−mTm + T−mU1,m)
++ α3
+0
+12
+�
+m,n>0
+(U1,−mU1,−nU1,m+n + U1,−m−nU1,mU1,n)×
+×
+�mn(2 + 2qm+n + qm + qn)
+(1 − qm)(1 − qn)
++ m(m + n)(2qm + 1 + 2qm+n + q2m+n)
+(1 − qm)(1 − qm+n)
++ n(m + n)(2qn + 1 + 2qm+n + qm+2n)
+(1 − qn)(1 − qm+n)
+�
++ α3
+0
+�
+m>0
+m2qm
+(1 − qm)2 U1,−mU1,mU1,0 + α3
+0
+6
+�
+m>0
+m2U1,−mU1,mU1,0
++ α4
+0N2
+2
+�
+m>0
+m3qm(1 + qm)
+(1 − qm)3
+U1,−mU1,m
++ α2
+0(1 + α2
+0 − 4α2
+0N + α2
+0N2)
+24
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m
+− α0E2
+8
+φ3,0 − α2
+0E2
+8
+�
+m>0
+m(1 + qm)
+1 − qm
+U1,−mU1,m
+(C.51)
++ α2
+0N E4 − E2
+2
+144
+T0 + 3α2
+0
+�
+m>0
+m2qm
+1 − qm T0 + α2
+0
+2
+E4 − E2
+2
+288
+U 2
+1,0
++ 3α3
+0N
+2
+�
+m>0
+m3qm
+(1 − qm)2 U1,0 − α3
+0(N − 1)
+2
+�
+m>0
+m3qm
+1 − qm U1,0
++ α3
+0N2
+2
+−2E6 + 3E2E4 − E3
+2
+1728
+U1,0 + α0E2
+2
+192 U1,0 + α0(1 + α2
+0 + Nα2
+0)E4
+480
+U1,0
++ α4
+0N3
+4
+�
+m>0
+m4qm(1 + qm)
+(1 − qm)3
++ α4
+0N2
+24
+�
+m>0
+m4qm(1 + 2qm)
+(1 − qm)2
+− α4
+0N2(N − 1)
+6
+�
+m>0
+m4qm
+(1 − qm)2 − α2
+0NE2
+8
+�
+m>0
+m2qm
+1 − qm
++ α2
+0N(3 + 3α2
+0 + α2
+0N)
+12
+�
+m>0
+m4qm
+1 − qm
++ α2
+0N2
+3456 (−E2E4 + E3
+2) − α2
+0(1 + α2
+0 + Nα2
+0)N2
+4320
+(E6 − E2E4)
++ α2
+0N2
+72
+−2E6 − 3E2E4 + 5E3
+2
+720
++ α4
+0N4
+24
+3E2
+4 − 8E2E6 + 6E2
+2E4 − E4
+2
+6912
+C.6
+Lowest weight expectation value
+Here we list the eigenvalues of lowest ILW Hamiltonians when acting on the lowest weight
+state. We have
+(log Hq)1,hw = −α0
+�
+−u2 + u2
+1
+2 − N
+24
+�
++ α0NE2
+24
+(C.52)
+(log Hq)2,hw = α0
+2
+�
+u3 − u1u2 + 1
+3u3
+1 − u1
+12
+�
+− α0E2
+24 u1
+– 84 –
+
++ α2
+0N2 E4 − E2
+2
+576
++ α2
+0N
+2
+�
+m>0
+m2qm
+1 − qm
+(C.53)
+(log Hq)3,hw = α0
+3
+�α2
+0N2
+480 − α2
+0N
+160 − 7N
+960 + u2
+1u2 − u4
+1
+4 + u2
+1
+8 − u1u3 − u2
+2
+2 − u2
+4 + u4
+�
++ α0E2
+12
+�
+−u2 + u2
+1
+2 − N
+24
+�
+− α2
+0N E4 − E2
+2
+288
+u1 − α2
+0
+�
+m>0
+m2qm
+1 − qm u1
+(C.54)
++ α3
+0N3 2E6 − 3E2E4 + E3
+2
+10368
++ α3
+0N(N − 1)
+6
+E4 − 1
+240
+− α3
+0N2
+2
+�
+m>0
+m3qm
+(1 − qm)2 − Nα0(1 + α2
+0 + Nα2
+0)E4
+1440
+− Nα0E2
+2
+576
+(log Hq)4,hw = +α0
+4
+�
+u5 − u1u4 − u2u3 + u2
+1u3 + u1u2
+2 − u3
+1u2 + u5
+1
+5
+− u3
+2 + u1u2
+2
+− u3
+1
+6 − (2α2
+0N − 6α2
+0 − 7)u1
+240
+�
+− α0E2
+8
+�
+u3 − u1u2 + u3
+1
+3 − u1
+12
+�
++ α2
+0N E4 − E2
+2
+144
+�
+−u2 + u2
+1
+2 − N
+24
+�
++ 3α2
+0
+�
+m>0
+m2qm
+1 − qm
+�
+−u2 + u2
+1
+2 − N
+24
+�
++ α2
+0
+2
+E4 − E2
+2
+288
+u2
+1
+(C.55)
++ 3α3
+0N
+2
+�
+m>0
+m3qm
+(1 − qm)2 u1 − α3
+0(N − 1)
+2
+E4 − 1
+240
+u1
++ α3
+0N2
+2
+−2E6 + 3E2E4 − E3
+2
+1728
+u1 + α0E2
+2
+192 u1 + α0(1 + α2
+0 + Nα2
+0)E4
+480
+u1
++ α4
+0N3
+4
+�
+m>0
+m4qm(1 + qm)
+(1 − qm)3
++ α4
+0N2
+24
+�
+m>0
+m4qm(1 + 2qm)
+(1 − qm)2
+− α4
+0N2(N − 1)
+6
+�
+m>0
+m4qm
+(1 − qm)2 − α2
+0NE2
+8
+�
+m>0
+m2qm
+1 − qm
++ α2
+0N(3 + 3α2
+0 + α2
+0N)
+12
+�
+m>0
+m4qm
+1 − qm
++ α2
+0N2
+3456 (−E2E4 + E3
+2) − α2
+0(1 + α2
+0 + Nα2
+0)N2
+4320
+(E6 − E2E4)
++ α2
+0N2
+72
+−2E6 − 3E2E4 + 5E3
+2
+720
++ α4
+0N4
+24
+3E2
+4 − 8E2E6 + 6E2
+2E4 − E4
+2
+6912
+– 85 –
+
+The expectation values of the power sums of Yangian Bethe roots Ok as defined in that we
+used in this calculation are given by
+⟨O0⟩ =
+�
+m>0
+d−m = 1 − E2
+24
+(C.56)
+⟨O1⟩ = α0
+2
+�
+m>0
+(1 − dm + d−m)d−m = α0(1 − E2)
+48
+− α0
+2
+�
+k>0
+k2qk
+1 − qk
+(C.57)
+⟨O2
+0⟩c =
+�
+m>0
+dmd−m = E4 − E2
+2
+288
+(C.58)
+⟨O2⟩ =
+�
+m>0
+�7 + 4α2
+0
+12
+(d3
+−m − 2d2
+−mdm + d−md2
+m) + α2
+0
+2 d2
+−m − 1 + α2
+0
+2
+d−mdm − 1 − 2α2
+0
+12
+d−m
+�
+= 16α2
+0 − 17
+2880
++ (1 − 2α2
+0)E2
+288
++ (1 + 2α2
+0)E4
+1440
++ E2
+2
+576 − α2
+0
+2
+�
+k>0
+k2qk
+1 − qk
+(C.59)
+⟨O0O1⟩c = α0
+4
+�
+m>0
+(d2
+−mdm − d−md2
+m + d−mdm) = α0(E4 − E2
+2)
+576
+− α0
+2
+�
+k>0
+k3qk
+(1 − qk)2
+(C.60)
+⟨O3
+0⟩c =
+�
+m>0
+(d2
+−mdm + d−md2
+m) = −2E6 + 3E2E4 − E3
+2
+1728
+(C.61)
+⟨O3⟩ = −α0(4α2
+0 + 17)
+1920
++ α0E2
+192 + α0(1 + 2α2
+0)E4
+960
++ α0E2
+2
+384
++ α0(1 − 2α2
+0 + E2)
+8
+�
+k>0
+k2qk
+1 − qk − α0(1 + α2
+0)
+4
+�
+k>0
+k4qk
+1 − qk
+(C.62)
+⟨O0O2⟩c =
+�
+m>0
+�7 + 4α2
+0
+12
+(d3
+−mdm − 2d2
+−md2
+m + d−md3
+m)
+− 1 − α2
+0
+2
+d2
+−mdm − 1 + α2
+0
+2
+d−md2
+m − 1 − 2α2
+0
+12
+d−mdm
+�
+(C.63)
+= −4E6 − E2E4 + 5E3
+2
+17280
+− α2
+0(E6 − E2E4)
+2160
+− (1 − 2α2
+0)(E4 − E2
+2)
+3456
+− α2
+0
+2
+�
+k>0
+k3qk
+(1 − qk)2
+⟨O2
+1⟩c =
+�
+m>0
+�4 + 3α2
+0
+12
+(d3
+−mdm − 2d2
+−md2
+m + d−md3
+m)
+− 2 − 3α2
+0
+2
+d2
+−mdm − 2 + 3α2
+0
+2
+d−md2
+m + α2
+0
+4 d−mdm
+�
+(C.64)
+= −2E6 − 3E2E4 + 5E3
+2
+25920
++ α2
+0(E4 − E2
+2)
+1152
++ α2
+0(−E6 + E2E4)
+2880
+− α2
+0
+2
+�
+k>0
+k3qk
+(1 − qk)2
+⟨O2
+0O1⟩c = α0
+2
+�
+m>0
+(d3
+−mdm − d−md3
+m + d2
+−mdm + d−md2
+m)
+= −α0(2E6 − 3E2E4 + E3
+2)
+3456
+− α0
+2
+�
+k>0
+k4qk(1 + qk)
+(1 − qk)3
+(C.65)
+– 86 –
+
+⟨O4
+0⟩c =
+�
+m>0
+(d3
+−mdm + 4d2
+−md2
+m + d−md3
+m) = 3E2
+4 − 8E2E6 + 6E2
+2E4 − E4
+2
+6912
+(C.66)
+D
+Level 1 test of FJMM
+In this appendix we make another test of Feigin-Jimbo-Miwa-Mukhin formula. In the main
+text we were calculating the individual terms of the asymptotic expansions at u → ∞ to
+all orders in q, i.e. our formulas were perturbative in u but exact in q. On the other hand,
+the matrix elements of R in the Fock representations can be evaluated as exact functions
+of u (which are up to an overall normalization just rational functions).
+The test that we want to do here will be to calculate the exact eigenvalue of Hq(u) on
+level 1 excited state |□⟩ in free boson Fock space (i.e. N = 1). The result is expressed as
+a sum over Young diagrams labeling states in the auxiliary space, but the summand will
+have slightly different structure than in FJMM formula. The strategy is the same one that
+we followed in section 5.3 when calculating the vacuum eigenvalue of Hq(u): we need to
+evaluate
+1
+�
+λ q|λ|
+�
+λ
+q|λ| ⟨□| ⊗ ⟨λ| R(u) |□⟩ ⊗ |λ⟩ ,
+(D.1)
+therefore it is enough to find spectrum of the operator
+⟨□| R(u) |□⟩
+(D.2)
+acting on the auxiliary Fock space.
+D.1
+Yangian algebra from R-matrix and useful identity
+Matrix elements of R-matrix between simple Fock states such as (D.2) are exactly what
+leads to Yangian currents such as ψ(u), e(u) and f(u) [39, 41]. In this section we will review
+this construction mainly to fix the notation and also derive an identity (D.47) following [41].
+This identity is exactly what allows us to understand the spectrum of (D.2).
+We start with (N = 1, ¯N = 1) R-matrix normalized such that it acts on the vacuum
+as identity and at level one we have
+R(u) |□⟩ ⊗ |0⟩ =
+u
+u + ϵ3
+|□⟩ ⊗ |0⟩ +
+ϵ3
+u + ϵ3
+|0⟩ ⊗ |□⟩
+(D.3)
+R(u) |0⟩ ⊗ |□⟩ =
+ϵ3
+u + ϵ3
+|□⟩ ⊗ |0⟩ +
+u
+u + ϵ3
+|0⟩ ⊗ |□⟩
+(D.4)
+⟨□| ⊗ ⟨0| R(u) =
+u
+u + ϵ3
+⟨□| ⊗ ⟨0| +
+ϵ3
+u + ϵ3
+⟨0| ⊗ ⟨□|
+(D.5)
+⟨0| ⊗ ⟨□| R(u) =
+ϵ3
+u + ϵ3
+⟨□| ⊗ ⟨0| +
+u
+u + ϵ3
+⟨0| ⊗ ⟨□|
+(D.6)
+As explained in [39], these matrix elements can be evaluated easily from the definition (2.3).
+In the following, we will study matrix elements of R-matrix with auxiliary space being
+one of single free boson (Heisenberg algebra Fock space) while the quantum space will be
+a general one. We need to choose which of the two spaces we choose as the auxiliary space
+(the space where we take the matrix elements) and which one is the quantum space. We will
+– 87 –
+
+follow the convention of the main text, taking the right (barred) space as the auxiliary space
+and the left space as the quantum space. This is the convention used in [41] and the opposite
+of the one used in [39]. For calculation of (D.2) it would actually be more convenient to
+use the opposite convention, but with the current choice we can more easily compare to the
+main text. Both conventions are exchanged by taking u → −u or R(u) → R(u)−1 so we
+can easily obtain results for the other choice.
+We can now define (see sections 3.5 and 3.6 in [39])
+H(u) = ⟨0|A RQA(u) |0⟩A
+(D.7)
+E(u) = ⟨0|A RQA(u) |□⟩A
+(D.8)
+F(u) = ⟨□|A RQA(u) |0⟩A
+(D.9)
+and
+e(u) = H(u)−1E(u)
+(D.10)
+f(u) = F(u)H(u)−1
+(D.11)
+which differs from the conventions of [39] only by an overall constant. Consider now three
+spaces, auxiliary spaces HA and HB and the quantum space HQ. The Yang-Baxter equation
+for such three spaces reads
+RQA(u)RQB(v)RAB(v − u) = RAB(v − u)RQB(v)RQA(u).
+(D.12)
+Level 0 → 0 relations
+Taking the vacuum-to-vacuum matrix element in auxiliary Fock
+spaces we find immediately
+⟨0|A ⟨0|B RQA(u)RQB(v)RAB(v − u) |0⟩A |0⟩B =
+= ⟨0|A ⟨0|B RAB(v − u)RQB(v)RQA(u) |0⟩A |0⟩B
+(D.13)
+or in other words
+⟨0|A RQA(u) |0⟩A ⟨0|B RQB(v) |0⟩B = ⟨0|B RQB(v) |0⟩B ⟨0|A RQA(u) |0⟩A
+(D.14)
+which is by definition
+H(u)H(v) = H(v)H(u).
+(D.15)
+We used the fact that the R-matrix used in this section is normalized such that it preserves
+the vacuum state,
+RAB(u) |0⟩A |0⟩B = |0⟩A |0⟩B
+(D.16)
+⟨0|A ⟨0|B RAB(u) = ⟨0|A ⟨0|B .
+(D.17)
+By taking the vacuum-to-vacuum matrix element in the auxiliary space we found a gen-
+erating function of Yangian Hamiltonians, discovering one of the integrable structures of
+W1+∞. Let us now turn to ladder operators.
+– 88 –
+
+Level 0 ↔ 1 relations
+Taking matrix elements between vacuum and level 1 state in the
+auxiliary space (4 matrix elements), we find 2 equations for creation operator
+⟨•, •| RQA(u)RQB(v)RAB(v − u) |□, •⟩ = ⟨•, •| RAB(v − u)RQB(v)RQA(u) |□, •⟩ (D.18)
+⟨•, •| RQA(u)RQB(v)RAB(v − u) |•, □⟩ = ⟨•, •| RAB(v − u)RQB(v)RQA(u) |•, □⟩ (D.19)
+or explicitly
+(u − v)E(u)H(v) − ϵ3H(u)E(v) = (u − v − ϵ3)H(v)E(u)
+(D.20)
+−ϵ3E(u)H(v) + (u − v)H(u)E(v) = (u − v − ϵ3)E(v)H(u).
+(D.21)
+These two equations are not independent: taking for example the first equation as it is
+and the same equation with u ↔ v exchanged, we can eliminate from these two equations
+H(v)E(u) and the resulting quantities satisfy the second equation. In fact, we have four
+different ways of ordering H and E evaluated at u and v so there are four different equations
+with one of these quantities missing. Multiplying the first equation in (D.20) by H(u)−1
+from the left and using the commutativity of H as well as the definition of e(u) we can
+write equivalently
+(u − v)e(u)H(v) − ϵ3E(v) = (u − v − ϵ3)H(v)e(u).
+(D.22)
+Multiplying this from the left by H(v)−1, we find
+(u − v − ϵ3)e(u) = (u − v)H(v)−1e(u)H(v) − ϵ3e(v).
+(D.23)
+Sending v → u − ϵ3,
+e(u + ϵ3)H(u) = H(u)e(u) = E(u).
+(D.24)
+In particular, we find
+e(u) = H(u)−1E(u) = E(u − ϵ3)H(u − ϵ3)−1
+(D.25)
+For the annihilation operators, we have the following 2 equations
+⟨□, •| RQA(u)RQB(v)RAB(v − u) |•, •⟩ = ⟨□, •| RAB(v − u)RQB(v)RQA(u) |•, •⟩ (D.26)
+⟨•, □| RQA(u)RQB(v)RAB(v − u) |•, •⟩ = ⟨•, □| RAB(v − u)RQB(v)RQA(u) |•, •⟩ (D.27)
+or explicitly
+(u − v − ϵ3)F(u)H(v) = (u − v)H(v)F(u) − ϵ3F(v)H(u)
+(D.28)
+(u − v − ϵ3)H(u)F(v) = −ϵ3H(v)F(u) + (u − v)F(v)H(u)
+(D.29)
+Level 1 → 1 relations
+Taking the matrix elements between level 1 states in the auxiliary
+space (4 matrix elements in total), we find equations
+⟨□, •| RQA(u)RQB(v)RAB(v − u) |□, •⟩ = ⟨□, •| RAB(v − u)RQB(v)RQA(u) |□, •⟩
+(D.30)
+– 89 –
+
+⟨•, □| RQA(u)RQB(v)RAB(v − u) |□, •⟩ = ⟨•, □| RAB(v − u)RQB(v)RQA(u) |□, •⟩
+(D.31)
+⟨□, •| RQA(u)RQB(v)RAB(v − u) |•, □⟩ = ⟨□, •| RAB(v − u)RQB(v)RQA(u) |•, □⟩
+(D.32)
+⟨•, □| RQA(u)RQB(v)RAB(v − u) |•, □⟩ = ⟨•, □| RAB(v − u)RQB(v)RQA(u) |•, □⟩
+(D.33)
+Using now the explicit expressions for matrix elements of RAB (D.3), we simplify this to
+(u − v) [H(v), L□,□(u)] = −ϵ3 (F(u)E(v) − F(v)E(u))
+(D.34)
+(u − v) [E(u), F(v)] = −ϵ3 (H(v)L□,□(u) − H(u)L□,□(v))
+(D.35)
+(u − v) [E(v), F(u)] = −ϵ3 (L□,□(u)H(v) − L□,□(v)H(u))
+(D.36)
+(u − v) [H(u), L□,□(v)] = −ϵ3 (E(v)F(u) − E(u)F(v))
+(D.37)
+where
+L□,□(u) ≡ ⟨□|A RQA(u) |□⟩A .
+(D.38)
+Let us now construct the ψ operator following [41]. We start with the equation (D.36) and
+write it as
+(u−v)E(v)H−1(v)H(v)F(u)−(u−v)F(u)H−1(u)H(u)E(v) = −ϵ3 (L□,□(u)H(v) − L□,□(v)H(u))
+(D.39)
+We now use (D.28) and (D.21) and find
+− ϵ3L□,□(u)H(v) + ϵ3L□,□(v)H(u) = ϵ3E(v)H−1(v)F(v)H(u) − ϵ3F(u)H−1(u)E(u)H(v)
++ (u − v − ϵ3)E(v)H−1(v)F(u)H(v) − (u − v − ϵ3)F(u)H−1(u)E(v)H(u)
+(D.40)
+Multiplying by H−1(u)H−1(v) from the right and using the definition of e(u) and f(u),
+−ϵ3L□,□(u)H−1(u)+ϵ3L□,□(v)H−1(v) = ϵ3E(v)H−1(v)F(v)H−1(v)−ϵ3F(u)H−1(u)E(u)H−1(u)
++ (u − v − ϵ3)E(v)H−1(v)F(u)H−1(u) − (u − v − ϵ3)F(u)H−1(u)E(v)H−1(v)
+(D.41)
+Expressing terms proportional to (u−v−ϵ3) in terms of f(u) and e(u+ϵ3) and rearranging
+the result, we see that
+−
+ϵ3
+u − v − ϵ3
+�
+L□,□(u)H−1(u) − L□,□(v)H−1(v) + E(v)H−1(v)F(v)H−1(v)
+− F(u)H−1(u)E(u)H−1(u)
+�
+= [e(v + ϵ3), f(u)] .
+(D.42)
+Shifting v → v − ϵ3 (and renaming u and v) we finally find
+(u − v) [e(u), f(v)] = −ϵ3
+�
+ψ(u) − ˜ψ(v)
+�
+(D.43)
+where
+ψ(u + ϵ3) ≡ L□,□(u)H−1(u) − E(u)H−1(u)F(u)H−1(u)
+(D.44)
+– 90 –
+
+˜ψ(u) ≡ L□,□(u)H−1(u) − F(u)H−1(u)E(u)H−1(u)
+(D.45)
+Choosing u = v, the left-hand side vanishes while the form of the right-hand side implies a
+consistency relation
+ψ(u) = ˜ψ(u)
+(D.46)
+which can equivalently be written as
+e(u)f(u − ϵ3) − f(u)e(u + ϵ3) = L□,□(u − ϵ3)H−1(u − ϵ3) − L□,□(u)H−1(u).
+(D.47)
+D.2
+Level 1 eigenvalue of Hq(u)
+Let us now restrict to N = 1 = ¯N. The spectrum of H(u) and ψ(u) are given by the usual
+Yangian expressions
+H(u) ↔
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+(D.48)
+and
+ψ(u) ↔ ψλ(u) ≡ u − ϵ3
+u
+×
+�
+□∈λ
+(u − ϵ□ + ϵ1)(u − ϵ□ + ϵ2)(u − ϵ□ + ϵ3)
+(u − ϵ□ − ϵ1)(u − ϵ□ − ϵ2)(u − ϵ□ − ϵ3)
+(D.49)
+where λ is a Young diagram labeling the common eigenstate of H(u) and ψ(u).
+The relations that we just found allow us to calculate the matrix elements of L□,□(u):
+(D.44)-(D.45) can be written as
+L□,□(u) = [ψ(u) + f(u)e(u + ϵ3)] H(u)
+(D.50)
+= [ψ(u + ϵ3) + e(u + ϵ3)f(u)] H(u)
+(D.51)
+Taking the diagonal matrix element of the first formula, between the eigenstate |λ⟩ of ψ(u),
+we find
+⟨λ| L□,□(u) |λ⟩ =
+�
+�ψλ(u) + #
+�
+□∈λ+
+F(λ + □ → λ)E(λ → λ + □)
+(u − ϵ□)(u − ϵ□ + ϵ3)
+�
+� ×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+=
+�
+�ψλ(u) − ϵ3
+�
+□∈λ+
+resu→ϵ□ ψλ(u)
+(u − ϵ□)(u − ϵ□ + ϵ3)
+�
+� ×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+(D.52)
+In the second line we used the fact that the product of creation and annihilation amplitudes
+can be expressed in terms of the residue of the generating function ψλ(u) [27]. Analogously,
+the second formula implies
+⟨λ| L□,□(u) |λ⟩ =
+�
+�ψλ(u + ϵ3) + #
+�
+□∈λ−
+F(λ → λ − □)E(λ − □ → λ)
+(u − ϵ□)(u − ϵ□ + ϵ3)
+�
+� ×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+=
+�
+�ψλ(u + ϵ3) + ϵ3
+�
+□∈λ−
+resu→ϵ□ ψλ(u)
+(u − ϵ□)(u − ϵ□ + ϵ3)
+�
+� ×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+.
+(D.53)
+– 91 –
+
+We can now use the partial fraction expansion
+1
+(u − ϵ□)(u − ϵ□ + ϵ3) = 1
+ϵ3
+1
+u − ϵ□
+− 1
+ϵ3
+1
+u − ϵ□ + ϵ3
+(D.54)
+as well as the fact that ψλ(u) is determined once we know the positions of its simple poles
+and the corresponding residues,
+ψλ(u) = 1 +
+�
+□∈λ+
+resu→ϵ□ ψλ(u)
+u − ϵ□
++
+�
+□∈λ−
+resu→ϵ□ ψλ(u)
+u − ϵ□
+.
+(D.55)
+Here we used the shell-formula [27], the fact that ψλ(u) has only simple poles and these
+poles are at positions of boxes which can be added or removed consistently with the Young
+diagram rules.
+We also used the fact that the value of ψλ(u) at infinity is equal to 1.
+Plugging this into (D.52), we finally find
+⟨λ| L□,□(u) |λ⟩ =
+�
+�1 +
+�
+□∈λ+
+resu→ϵ□ ψλ(u)
+u + ϵ3 − ϵ□
++
+�
+□∈λ−
+resu→ϵ□ ψλ(u)
+u − ϵ□
+�
+� ×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+.
+(D.56)
+Using the second formula for L□,□(u) would lead to the same result.
+We see that the
+diagonal matrix element of L□,□(u) between eigenstates of Yangian Hamiltonians is up to
+a contribution from H(u) eigenvalue given by decomposing ψλ(u) into partial fractions and
+shifting the poles associated to addable boxes by −ϵ3 while leaving the poles associated to
+removable boxes intact. We can now write the formula for Hq(u) eigenvalue at level 1 as
+Hq(u) ↔
+1
+�
+λ q|λ|
+�
+λ
+q|λ|
+�
+�1 +
+�
+□∈λ+
+resu→ϵ□ ψλ(u)
+u − ϵ□ + ϵ3
++
+�
+□∈λ−
+resu→ϵ□ ψλ(u)
+u − ϵ□
+�
+�×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+(D.57)
+which is a closed form formula valid exactly to all orders in u.
+Now we can compare this eigenvalue with the FJMM formula.
+More precisely, we
+calculate
+X = ⟨□| Hq(u) |□⟩ ×
+�
+λ q|λ| × �
+□∈λ
+u−ϵ□
+u−ϵ□+ϵ3
+⟨0| Hq(u) |0⟩
+(D.58)
+in two different ways (the second factor is introduced to fix the normalization). From the
+derivation in this appendix, we have
+X =
+�
+λ
+q|λ|
+�
+�1 +
+�
+□∈λ+
+resu→ϵ□ ψλ(u)
+u − ϵ□ + ϵ3
++
+�
+□∈λ−
+resu→ϵ□ ψλ(u)
+u − ϵ□
+�
+� ×
+�
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+(D.59)
+On the other hand, from BAE we see that there is only one Bethe root equal to
+x = − ϵ3q
+1 − q
+(D.60)
+– 92 –
+
+and the FJMM formula takes the form
+X =
+u − x
+u − x + ϵ3
+�
+λ
+q|λ| �
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+ϕ(u − x − ϵ□ + ϵ3)
+(D.61)
+=
+�
+λ
+q|λ|ψλ
+�
+u +
+ϵ3
+1 − q
+� �
+□∈λ
+u − ϵ□
+u − ϵ□ + ϵ3
+(D.62)
+Both formulas are exact to all orders in u and can be compared perturbatively in small q
+expansion. We checked that they agree to order O(q27). It is interesting that the effect of
+splitting the poles corresponding to addable and removable boxes and shifting the addable
+boxes by −ϵ3 in (D.59) is equivalent to translating the argument of ψλ(u) by q-dependent
+Bethe root as in (D.61).
+E
+Expansions of ILW Hamiltonians in the local limit
+E.1
+ILW Hamiltonians with rational matrix elements
+Here we summarize the ILW conserved quantities obtained from (log H)j by change of
+normalization and more importantly subtraction of the transcendental and central terms:
+A1 = T0
+(E.1)
+A2 = −1
+2φ3,0 − α0
+2
+�
+m>0
+m1 + qm
+1 − qm U1,−mU1,m
+(E.2)
+A3 = −1
+3φ4,0 + α0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mTm + T−mU1,m)
+− α2
+0(N + 2)
+12
+�
+m>0
+m2U1,−mU1,m + α2
+0N
+4
+�
+m>0
+m2(1 + qm)2
+(1 − qm)2
+U1,−mU1,m
+(E.3)
+A4 = −1
+4φ5,0 − α0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−mφ3,m + φ3,−mU1,m)
+− α0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+T−mTm − α2
+0(2N − 3)
+12
+�
+m>0
+m2(U1,−mTm + T−mU1,m)
+− α2
+0N
+�
+m>0
+m2qm
+(1 − qm)2 (U1,−mTm + T−mU1,m)
+− α2
+0
+12
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)×
+×
+�
+2dm1dm2 + d−m1dm2 + dm1d−m2 + 2d−m1d−m2
+(E.4)
++ dm1dm1+m2 + 2d−m1dm1+m2 + 2dm1d−m1−m2 + d−m1d−m1−m2
++ dm2dm1+m2 + 2d−m2dm1+m2 + 2dm2d−m1−m2 + d−m2d−m1−m2
+�
+− α2
+0
+�
+m>0
+m2qm
+(1 − qm)2 U1,−mU1,mU1,0 − α2
+0
+6
+�
+m>0
+m2U1,−mU1,mU1,0
+– 93 –
+
+− α3
+0N2
+2
+�
+m>0
+m3qm(1 + qm)
+(1 − qm)3
+U1,−mU1,m
+− α0(1 + α2
+0 − 4α2
+0N + α2
+0N2)
+24
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m
+A5 = −1
+5φ6,0 − α0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(U1,−m ˜φ4,m + ˜φ4,−mU1,m)
++ α0
+2
+�
+m>0
+m(1 + qm)
+1 − qm
+(T−mφ3,m + φ3,−mTm)
++ α2
+0(N − 2)
+6
+�
+m>0
+m2(U1,−mφ3,m + φ3,−mU1,m)
++ α2
+0(N − 2)
+6
+�
+m>0
+m2T−mTm + α2
+0N
+�
+m>0
+m2qm
+(1 − qm)2 T−mTm
++ α0
+12
+�
+m>0
+m3(1 + qm)
+1 − qm
+(U1,−mTm + T−mU1,m)
++ (N − 1)(N − 2)α3
+0
+24
+�
+m>0
+m3(1 + qm)
+1 − qm
+(U1,−mTm + T−mU1,m)
++ α3
+0N2
+2
+�
+m>0
+m3qm(1 + qm)
+(1 − qm)3
+(U1,−mTm + T−mU1,m)
++ α2
+0N
+�
+m>0
+m2qm
+(1 − qm)2 (U1,−mφ3,m + φ3,−mU1,m)
+(E.5)
++ α4
+0N3
+6
+�
+m>0
+m4qm(1 + 4qm + q2m)
+(1 − qm)4
+U1,−mU1,m
++ α2
+0N(1 + α2
+0 + Nα2
+0)
+36
+�
+m>0
+m4(1 + 4qm + q2m)
+(1 − qm)2
+U1,−mU1,m
++ α2
+0N
+4
+�
+m>0
+m4qm
+(1 − qm)2 U1,−mU1,m
++ α4
+0N(N2 − 4N + 1)
+12
+�
+m>0
+m4qm
+(1 − qm)2 U1,−mU1,m
++ α2
+0
+72(3N + α2
+0 + 2Nα2
+0 + N2α2
+0)
+�
+m>0
+m4U1,−mU1,m
++ α4
+0(N − 1)3
+120
+�
+m>0
+m4U1,−mU1,m
++ α3
+0N
+6
+I4,3 + α4
+0(N − 1)
+240
+I5,1 + α3
+0
+24I5,2 + α3
+0N
+144 I5,3
+− α3
+0(N − 1)
+24
+I5,5 + α2
+0
+3 I5,4 + α2
+0
+6 I5,6
+– 94 –
+
+where
+I4,3 = 3
+2
+�
+m1,m2>0
+(U1,−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2U1,m1+m2) ×
+×
+�
+dm1d−m1dm2 + dm1d−m1d−m2 + dm1dm2d−m2 + d−m1dm2d−m2 + dm1d−m1dm1+m2
++ dm1d−m1d−m1−m2 + dm2d−m2dm1+m2 + dm2d−m2d−m1−m2 + dm1dm1+m2d−m1−m2
++ d−m1dm1+m2d−m1−m2 + dm2dm1+m2d−m1−m2 + d−m2dm1+m2d−m1−m2
+�
+(E.6)
++ 6U1,0
+�
+m>0
+(d2
+md−m + dmd2
+−m)U1,−mU1,m
+I5,1 = −8N
+�
+m>0
+m4(2 + qm + 2q2m)
+(1 − qm)2
+U1,−mU1,m
+(E.7)
+I5,2 = −
+�
+m1,m2>0
+(m2
+1 + m1m2 + m2
+2)(dm1+m2 + d−m1−m2 + dm1 + d−m1 + dm2 + d−m2)×
+× (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)
+(E.8)
+− 2N
+�
+m>0
+m3(1 + qm)
+1 − qm
+(T−mU1,m + U1,−mTm) − 4U1,0
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m
+I5,3 = 6
+�
+m1,m2>0
+�
+dm1dm2dm1+m2 + d−m1dm2dm1+m2 + dm1d−m2dm1+m2 + d−m1dm2d−m1−m2
++ dm1d−m2d−m1−m2 + d−m1d−m2d−m1−m2 + 3d−m1d−m2dm1+m2 + 3dm1dm2d−m1−m2
+�
+×
+× (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)
+(E.9)
+I5,4 =
+�
+m1,m2>0
+�
+dm1+m2dm2 + 2dm1+m2d−m2 + 2d−m1−m2dm2 + d−m1−m2d−m2
+�
+×
+×
+�
+U1,−m2T−m1U1,m1+m2 + U1,−m1−m2Tm1U1,m2
+�
++
+�
+m1,m2>0
+�
+dm1dm2 + 1
+2dm1d−m2 + 1
+2d−m1dm2 + d−m1d−m2
+�
+×
+(E.10)
+×
+�
+T−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2Tm1+m2
+�
++
+�
+m>0
+� 6m2qm
+(1 − qm)2 + m2
+�
+U1,−mT0U1,m
+I5,5 = 1
+2
+�
+m1,m2>0
+(U1,−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2U1,m1+m2)×
+×
+�
+− 2m2
+1d−m1 − 2m2
+2d−m2 − 8m1m2dm1 − 8m1m2dm2 − 8m2
+2dm1 − 8m2
+1dm2
++ 7m2
+1m2 + 7m1m2
+2 − 2(m1 − m2)2dm1+m2
+�
+(E.11)
+− 2U1,0
+�
+m>0
+m3(1 + qm)
+1 − qm
+U1,−mU1,m
+I5,6 =
+�
+m1,m2>0
+�
+m2(m1 + m2)(1 + 2qm2 + 2qm1+m2 + qm1+2m2)
+(1 − qm2)(1 − qm1+m2)
+×
+– 95 –
+
+×
+�
+T−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2Tm1+m2
++ U1,−m1−m2U1,m1Tm2 + T−m2U1,−m1U1,m1+m2
+�
++ m1m2(2 + qm1 + qm2 + 2qm1+m2)
+(1 − qm1)(1 − qm2)
+(U1,−m1−m2U1,m1Tm2 + T−m2U1,−m1U1,m1+m2)
+− 3
+m1m2qm1(1 + qm2)
+(1 − qm1)(1 − qm1+m2)
+�
+U1,−m1−m2 [U1,m1, Tm2] + [T−m2, U1,−m1] U1,m1+m2
+��
+− 1
+6
+�
+m>0
+m4U1,−mU1,m + 1
+60
+�
+m>0
+U1,−mU1,m
+(E.12)
++ 6U1,0
+�
+m>0
+m2qm
+(1 − qm)2 (U1,−mTm + T−mU1,m) + U1,0
+�
+m>0
+m2(U1,−mTm + T−mU1,m)
+These quantities have matrix elements which are manifestly rational functions of q with
+poles only at roots of unity, i.e. there are no transcendental terms such as the Eisenstein
+series. Their spectra in terms of solutions of Bethe ansatz equations are given by:
+A1 ⇝ p0 + hw.
+(E.13)
+A2 ⇝ p1 − α0
+2 p0 + hw.
+(E.14)
+A3 ⇝ p2 − α0p1 + 1 + 4α2
+0
+12
+p0 + hw.
+(E.15)
+A4 ⇝ p3 − 3α0
+2 p2 + 1 + 4α2
+0
+4
+p1 − α0(1 + 2α2
+0)
+8
+p0 + hw.
+(E.16)
+A5 ⇝ p4 − 2α0p3 + 1 + 4α2
+0
+2
+p2 − α0(1 + 2α2
+0)
+2
+p1 + 9 + 114α2
+0 − 4α2
+0N + 144α4
+0
+720
+p0 + hw.
+(E.17)
+E.2
+Local expansion of conserved quantities
+Here we list the expansion of Aj as q → 1:
+A2 ∼ − α0
+1 − q
+�
+m>0
+U1,−mU1,m +
+�
+− 1
+2φ3,0 + α0
+2
+�
+m>0
+U1,−mU1,m
+�
++ (1 − q)α0
+12
+�
+m>0
+(1 − m2)U1,−mU1,m + O((1 − q)2)
+(E.18)
+A3 ∼
+Nα2
+0
+(1 − q)2
+�
+m>0
+U1,−mU1,m +
+1
+1 − q
+�
+α0
+�
+m>0
+(U1,−mTm + T−mU1,m) − Nα2
+0
+�
+m>0
+U1,−mU1,m
+�
++
+�
+− 1
+3φ4,0 − α0
+2
+�
+m>0
+(U1,−mTm + T−mU1,m) − α2
+0(N + 2)
+12
+�
+m>0
+m2U1,−mU1,m
++ Nα2
+0
+12
+�
+m>0
+(1 + 2m2)U1,−mU1,m
+�
++ O((1 − q)1)
+(E.19)
+A4 ∼ − N2α3
+0
+(1 − q)3
+�
+m>0
+U1,−mU1,m
+– 96 –
+
++
+1
+(1 − q)2
+�
+− Nα2
+0
+�
+m>0
+(U1,−mTm + T−mU1,m) − α2
+0U1,0
+�
+m>0
+U1,−mU1,m
+− 3α2
+0
+2
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2) + 3N2α3
+0
+2
+�
+m>0
+U1,−mU1,m
+�
++
+1
+1 − q
+�
+− α0
+�
+m>0
+(U1,−mφ3,m + φ3,−mU1,m) − α0
+�
+m>0
+T−mTm
++ Nα2
+0
+�
+m>0
+(U1,−mTm + T−mU1,m) − α0(1 + α2
+0 − 4α2
+0N + α2
+0N2)
+12
+�
+m>0
+m2U1,−mU1,m
++ 3α2
+0
+2
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)
++ α2
+0U1,0
+�
+m>0
+U1,−mU1,m − N2α3
+0
+2
+�
+m>0
+U1,−mU1,m
+�
++ O((1 − q)0)
+(E.20)
+A5 ∼ + α4
+0N3
+(1 − q)4
+�
+m>0
+U1,−mU1,m
++
+1
+(1 − q)3
+�
+α3
+0N2 �
+m>0
+(T−mU1,m + U1,−mTm) + 2α3
+0NU1,0
+�
+m>0
+U1,−mU1,m
++ 7α3
+0N
+2
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)
+− 2α4
+0N3 �
+m>0
+U1,−mU1,m
+�
+1
+(1 − q)2
+�
++ 2α2
+0
+�
+m1,m2>0
+(T−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2Tm1+m2)
++ 2α2
+0
+�
+m1,m2>0
+(U1,−m2T−m1U1,m1+m2 + U1,−m1−m2Tm1U1,m2)
++ 2α2
+0
+�
+m1,m2>0
+(T−m2U1,−m1U1,m1+m2 + U1,−m1−m2U1,m1Tm2)
+(E.21)
+− 21α3
+0N
+4
+�
+m1,m2>0
+(U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)
++ 2α2
+0
+�
+m>0
+U1,−mT0U1,m + α2
+0N
+�
+m>0
+(U1,−mφ3,m + φ3,−mU1,m)
++ α2
+0N
+�
+m>0
+T−mTm − 3α3
+0NU1,0
+�
+m>0
+U1,−mU1,m − α2
+0
+3
+�
+m>0
+m2U1,−mU1,m
++ α2
+0U1,0
+�
+m>0
+(U1,−mTm + T−mU1,m) − 3α3
+0N2
+2
+�
+m>0
+(U1,−mTm + T−mU1,m)
++ 5α2
+0N
+12
+�
+m>0
+m2U1,−mU1,m + 5α4
+0N
+12
+�
+m>0
+m2U1,−mU1,m
+− α4
+0N2
+3
+�
+m>0
+m2U1,−mU1,m + α4
+0N3
+12
+�
+m>0
+m2U1,−mU1,m
+– 97 –
+
++ α2
+0
+3
+�
+m>0
+U1,−mU1,m + 7α4
+0N3
+6
+�
+m>0
+U1,−mU1,m
+�
++ O((1 − q)−1)
+Linear combinations of Aj that are finite in q → 1 limit
+B1 ≡ A1
+(E.22)
+B2 ≡ lim
+q→1 [(1 − q)A2]
+(E.23)
+B3 ≡ lim
+q→1 [(1 − q)A3 + α0NA2]
+(E.24)
+B4 ≡ lim
+q→1
+�
+(1 − q)2A4 + (1 − q)α0NA3
+�
+(E.25)
+B5 ≡ lim
+q→1
+�
+(1 − q)2A5 + (1 − q)7α0N
+3
+A4 + 4α2
+0N2
+3
+A3 + α3
+0N3
+6
+A2 − α2
+0Nu1
+3
+A2
+�
+.
+(E.26)
+In terms of mode operators, these are given by
+B1 = T0 + hw.
+(E.27)
+B2 = −α0
+2 (U1U1)0 + hw.
+(E.28)
+B3 = −α0N
+2
+W3,0 − α0U1,0T0 + α0
+3N (U1(U1U1))0 − α2
+0N
+4
+(U1U1)0 + hw.
+(E.29)
+B4 = −α2
+0
+2 (U1(U1U1))0 + α2
+0U1,0(U1U1)0 + α3
+0N2
+4
+(U1U1)0 + hw.
+(E.30)
+B5 = −4α2
+0N2
+9
+�
+W4,0 −
+3(N − 3)(α2
+0N2 + 3α2
+0N − 9)
+2N(5α2
+0N3 − 5α2
+0N − 5N − 17)(T∞T∞)0
+�
++ α2
+0
+2N
+�
+(U1(U1(U1U1)))0 − N(U ′
+1U ′
+1)0
+�
++ 2α2
+0N
+3
+T 2
+0 − α2
+0T0(U1U1)0
++ 3α2
+0N
+2
+U1,0W3,0 − α3
+0N3
+12
+W3,0
+(E.31)
+− α2
+0
+N U1,0(U1(U1U1))0 − 19α3
+0N
+36
+(U1(U1U1))0
++ 2α2
+0U 2
+1,0T0 − α3
+0N2
+6
+U1,0T0 − α2
+0N
+4
+T0
++ 4α3
+0N
+3
+U1,0(U1U1)0 + α2
+0(36 + 7α2
+0N3)
+72
+(U1U1)0 + hw.
+Their spectra in terms of Bethe roots are given by
+B1 ⇝ p0,0 + hw.
+(E.32)
+B2 ⇝ p1,−1 + hw.
+(E.33)
+B3 ⇝ p2,−1 + α0Np1,0 − α0p1,−1 − α2
+0N
+2
+p0,0 + hw.
+(E.34)
+B4 ⇝ p3,−2 + α0Np2,−1 + α2
+0N
+2
+p1,−1 + hw.
+(E.35)
+– 98 –
+
+B5 ⇝ p4,−2 + 7α0N
+3
+p3,−1 + 4α2
+0N2
+3
+p2,0 − 2α0p3,−2 − 7α2
+0N
+2
+p2,−1
++ α3
+0N2(N − 8)
+6
+p1,0 − α2
+0N
+3
+u1p1,0 + α0N(1 + 4α2
+0)
+12
+p1,−1
++ α2
+0N2(4 + 16α2
+0 − 3α2
+0N)
+36
+p0,0 + α3
+0N
+6
+u1p0,0
+(E.36)
+F
+Solutions of Bethe ansatz equations
+F.1
+Lee-Yang, ∆ = 0, level 3
+F.1.1
+Resultant
+The factor of resultant which gives all 15 physical roots corresponding to 5 states at level
+3 in ∆ = 0 representation of Lee-Yang is of the form
+15
+�
+j=0
+βjxj
+(F.1)
+with
+β15 = (q − 1)10(q + 1)2(q2 + q + 1)3
+β14 = −3(q − 1)9(q + 1)(q2 + q + 1)2(33q4 + 43q3 + 28q2 + 13q + 3)
+β13 = +2(q − 1)8(q2 + q + 1)(2233q8 + 5861q7 + 7678q6 + 6703q5 + 4118q4
++ 1915q3 + 622q2 + 65q − 35)
+β12 = −6(q − 1)7(20307q11 + 60224q10 + 99023q9 + 108981q8 + 87774q7 + 55299q6
++ 26595q5 + 8604q4 + 951q3 − 687q2 − 434q − 77)
+β11 = +3(q − 1)6(749783q12 + 1744223q11 + 2365345q10 + 2212756q9 + 1574487q8
++ 880113q7 + 336042q6 + 35985q5 − 44217q4 − 37388q3 − 16847q2 − 3361q + 839)
+β10 = −9(q − 1)5(3308679q13 + 5646690q12 + 6135516q11 + 4858939q10
++ 2992059q9 + 1255144q8 + 131899q7 − 313931q6 − 287540q5 − 159815q4
+− 52583q3 − 6224q2 + 5010q + 781)
+(F.2)
+β9 = +2(q − 1)4(146080348q14 + 161581637q13 + 135923944q12 + 92019809q11
++ 42057082q10 + 1378169q9 − 15764754q8 − 17393766q7 − 11748774q6 − 4558375q5
+− 907046q4 + 94313q3 + 226048q2 + 113861q − 23456)
+β8 = −12(q − 1)3(180333417q15 + 94388201q14 + 61100585q13 + 37723050q12
+− 47534q11 − 19473224q10 − 24531861q9 − 17036862q8 − 9470139q7 − 1708392q6
++ 40666q5 + 598774q4 + 313866q3 + 155033q2 − 55000q + 300)
+β7 = +8(q − 1)2(1525470224q16 − 67057602q15 + 58007498q14 + 64468027q13
+− 127940362q12 − 159580082q11 − 206469540q10 − 63924311q9 − 23482788q8
++ 977641q7 + 9511632q6 + 7954486q5 + 2154422q4 + 568675q3 − 139810q2
+− 191490q + 40100)
+– 99 –
+
+β6 = −48(q − 1)(1091911035q17 − 655148860q16 − 7896247q15 + 25788450q14
+− 29750149q13 − 132857401q12 − 117530061q11 + 20865566q10 + 14616293q9
+− 2642898q8 + 15160759q7 + 2887639q6 + 1689999q5 − 275210q4 + 195565q3
+− 378795q2 + 125350q − 12875)
+β5 = +288(590434004q18 − 679495775q17 + 105467922q16 + 57781429q15
++ 59562920q14 − 175016546q13 + 30903476q12 + 1357527q11 + 33182072q10
+− 9897385q9 + 7510916q8 + 292398q7 + 1384190q6 − 780377q5 + 92840q4
+− 172070q3 + 82650q2 − 16625q + 1250)
+β4 = −1728q3(236868899q15 − 167106540q14 − 27475861q13 + 30085783q12
++ 71194720q11 − 93267345q10 + 26586077q9 − 34251559q8 + 17589658q7
+− 3235715q6 − 1579579q5 + 967928q4 + 321965q3 − 16556q2 + 5065q + 100)
+β3 = +10368q6(68241566q12 − 18895570q11 − 20786934q10 + 7199369q9
++ 33561740q8 − 22673859q7 + 12236878q6 − 12682141q5 + 3702336q4
+− 429295q3 − 709332q2 + 75072q − 25990)
+β2 = −62208q9(13326500q9 + 1552000q8 − 5598873q7 − 169064q6 + 7716992q5
+− 2044760q4 + 2513825q3 − 1187532q2 + 408704q + 15928)
+β1 = +8211456q12(71676q6 + 32140q5 − 37217q4 − 23402q3 + 31535q2 − 268q + 4268)
+β0 = −8671297536q15(q − 1)(22q2 + 37q + 22)
+This expression is very long, but we should remember that it captures all the higher spin
+charges of all five physical states at level 3.
+F.1.2
+Yangian limit
+The q-expansion of the physical solutions around q = 0 is as follows:
+�
+�
+�
+�
+�
+�
+�
+−10 − 24
+13q + O(q2)
+−5 − 264
+65 q2 + O(q3)
+− 528
+25 q3 + 2376
+1625q4 + O(q5)
+(F.3)
+�
+�
+�
+�
+�
+�
+�
+−5 − 22
+7 q − +O(q2)
+132
+5 q3 + 6138
+25 q4 + O(q5)
+2 − 90
+7 q + O(q2)
+(F.4)
+�
+�
+�
+�
+�
+�
+�
+−5 − 39
+14q + O(q2)
+66
+5 q3 − 136176
+2275 q4 + O(q5)
+3 + 165
+26 q + O(q2)
+(F.5)
+�
+�
+�
+�
+�
+�
+�
+−12q3 − 1410
+7 q4 + O(q5)
+2 + 30
+7 q + O(q2)
+3 − 30q + O(q2)
+(F.6)
+– 100 –
+
+�
+�
+�
+�
+�
+�
+�
+−6q3 + 45q4 + O(q5)
+2 − 20q2 + O(q3)
+4 + 10q + O(q2)
+(F.7)
+F.1.3
+Local limit q → 1
+On the other hand, the expansion around the local point is more interesting. The five
+solutions have expansion around q = 1 as follows:
+�
+�
+�
+�
+�
+�
+�
+0 − 88
+81(1 − q) + 1496
+6561(1 − q)2 + O((1 − q)3)
+3 − 148
+81 (1 − q) − 74
+81(1 − q)2 + O((1 − q)3)
+6 − 88
+81(1 − q) − 8624
+6561(1 − q)2 + O((1 − q)3)
+(F.8)
+�
+�
+�
+�
+�
+�
+�
+−
+6
+1−q + 6 − 10
+3 (1 − q) − 5
+3(1 − q)2 + O((1 − q)3)
+6+
+√
+14
+2
+− 11
+12(1 − q) − 11(168+5
+√
+14)
+4032
+(1 − q)2 + O((1 − q)3)
+6−
+√
+14
+2
+− 11
+12(1 − q) − 11(168−5
+√
+14)
+4032
+(1 − q)2 + O((1 − q)3)
+(F.9)
+�
+�
+�
+�
+�
+�
+�
+−
+6
+1−q − 2
+2
+3 5
+1
+3 (1 − q)− 1
+3 + 6 + O((1 − q)
+1
+3 )
+−
+6
+1−q − 2
+2
+3 5
+1
+3 e− 2πi
+3 (1 − q)− 1
+3 + 6 + O((1 − q)
+1
+3 )
+−
+6
+1−q − 2
+2
+3 5
+1
+3 e
+2πi
+3 (1 − q)− 1
+3 + 6 + O((1 − q)
+1
+3 )
+(F.10)
+�
+�
+�
+�
+�
+�
+�
+−
+6
+1−q + 3 × 5
+1
+4 (1 − q)− 1
+2 − 19
+√
+5
+18
++ O((1 − q)
+1
+2 )
+−
+6
+1−q − 3 × 5
+1
+4 (1 − q)− 1
+2 − 19
+√
+5
+18
++ O((1 − q)
+1
+2 )
+−
+6
+1−q − 2(4
+√
+5−27)
+9
++ O((1 − q))
+(F.11)
+�
+�
+�
+�
+�
+�
+�
+−
+6
+1−q + 3i × 5
+1
+4 (1 − q)− 1
+2 + 19
+√
+5
+18
++ O((1 − q)
+1
+2 )
+−
+6
+1−q − 3i × 5
+1
+4 (1 − q)− 1
+2 + 19
+√
+5
+18
++ O((1 − q)
+1
+2 )
+−
+6
+1−q + 2(4
+√
+5+27)
+9
++ O((1 − q))
+(F.12)
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diff --git a/OtE4T4oBgHgl3EQfkA1f/content/tmp_files/load_file.txt b/OtE4T4oBgHgl3EQfkA1f/content/tmp_files/load_file.txt
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@@ -0,0 +1,3428 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf,len=3427
+page_content='Prepared for submission to JHEP  On Bethe equations of 2d conformal field theory  Tomáš Procházka,a Akimi Watanabeb  aInstitute of Physics AS CR  Na Slovance 2, Prague 8, Czech Republic  bDepartment of Physics, The University of Tokyo  7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033, Japan  E-mail: prochazkat@fzu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='cz, awatanabe@hep-th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='u-tokyo.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='ac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='jp  Abstract: We study the higher spin algebras of two-dimensional conformal field theory  from the perspective of quantum integrability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Starting from Maulik-Okounkov instanton R-  matrix and applying the procedure of algebraic Bethe ansatz, we obtain infinite commuting  families of Hamiltonians of quantum ILW hierarchy labeled by shape of the auxiliary torus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We calculate explicitly the first five of these Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Then, we numerically verify that  their joint spectrum can be parametriezed by solutions of Litvinov’s Bethe ansatz equations  and we conjecture a general formula for the joint spectrum of all ILW Hamiltonians, based  on results of Feigin, Jimbo, Miwa and Mukhin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  There are two interesting degeneration limits, the infinitely thick and the infinitely  thin auxiliary torus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In one of these limits, the ILW hierarchy degenerates to Yangian or  Benjamin-Ono hiearchy and the Bethe equations can be easily solved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The other limit is  singular but we can nevertheless extract local Hamiltonians corresponding to quantum KdV  or KP hierarchy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Litvinov’s Bethe equations in this local limit provide an alternative to  Bethe ansatz equations of Bazhanov, Lukyanov and Zamolodchikov, but are more trans-  parent, work at any rank and are manifestly symmetric under triality symmetry of W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Finally, we illustrate analytic properties of the solutions of Bethe equations in minimal  models, in particular for Lee-Yang CFT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The analytic structure of Bethe roots is very rich  as it reflects the whole representation theory of WN minimal models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='05147v1  [hep-th]  12 Jan 2023  Contents  1  Introduction  1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Summary of the paper  7  2  Instanton R-matrix  8  3  Universal R-matrix  11  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Universal R-matrix from fusion  12  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Drinfeľd’s relations I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  15  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Spectral shift and normalization of R(u)  16  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  Drinfeľd’s relations II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  17  4  ILW Hamiltonians  18  5  Spectrum and Bethe equations  23  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Normalization and higher Casimir charges  24  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Spectrum of ILW Hamiltonians at q → 0  25  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Ground state eigenvalue of ILW Hamiltonians  28  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  Spectrum of (log Hq)j and Bethe ansatz  29  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  Feigin-Jimbo-Miwa-Mukhin formula  31  6  Local limit q → 1  33  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Roots of unity and twisted subalgebras  43  7  Examples of solutions  44  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Lee-Yang model  44  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Argyres-Douglas minimal models  44  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Solutions of Bethe ansatz equations for ∆ = − 1  5  48  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Solutions of Bethe ansatz equations for ∆ = 0  55  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Perturbative expansion at q = 0 and residue formula  60  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Numerical tests in first unitary W4 model  61  8  Outlook  64  A Fourier expansions and conformal normal ordering  69  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 Complex plane  69  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 Cylinder  71  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3 Example - Virasoro algebra  73  B Large u expansion of R-matrix  74  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Mode expansions  74  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Large u expansion of R at N = 1  75  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Large u expansion of universal R  76  – i –  C Explicit expressions for ILW Hamiltonians  77  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 (Quasi-)modular forms  77  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 Calculation of expectation values in auxiliary space  78  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3 List of expectation values in auxiliary space  80  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 Third order ILW Hamiltonian  80  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5 Fourth order ILW Hamiltonian  81  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6 Lowest weight expectation value  84  D Level 1 test of FJMM  87  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 Yangian algebra from R-matrix and useful identity  87  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 Level 1 eigenvalue of Hq(u)  91  E Expansions of ILW Hamiltonians in the local limit  93  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ILW Hamiltonians with rational matrix elements  93  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Local expansion of conserved quantities  96  F Solutions of Bethe ansatz equations  99  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Lee-Yang, ∆ = 0, level 3  99  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Resultant  99  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Yangian limit  100  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Local limit q → 1  101  1  Introduction  Two-dimensional conformal field theory owes its solvability to infinite-dimensional symme-  try algebra, the Virasoro algebra,  [Lm, Ln] = (m − n)Lm+n + (m − 1)m(m + 1)  12  cδm+n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  In favourable situations, such as for so-called minimal models, the whole Hilbert space of  the theory decomposes into a finite number of irreducible representations of two commuting  copies of the Virasoro algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The surprising feature of these representations in contrast  to representations of complex semisimple algebras is the fact that the analogue of Cartan  subalgebra is only one-dimensional, spanned by a single generator, L0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All the other gen-  erators Lm, m ̸= 0 act as ladder operators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As consequence of this, the spectrum of L0 is  somewhat uninteresting, with all eigenvalues being of the form ∆ + n, n ≥ 0 where ∆ is the  L0 eigenvalue of the lowest weight vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The eigenspaces of L0 are highly degenerate, the  degeneracy going to infinity as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  By contrast, there is a larger class of solvable two-dimensional quantum field theory  models, whose solvability is due to existence of infinitely many commuting higher conserved  quantities [1–4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Examples of such models are the integrable deformations of 2d CFTs,  where one starts with a 2d conformal field theory in the UV and deforms it by a relevant  – 1 –  operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Perhaps the most famous example of such a model is the 2d Ising model in  transverse magnetic field [5] related to the exceptional Lie algebra E8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The question is if  two-dimensional QFTs with conformal symmetry can be understood from the point of view  of this more robust framework of integrability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' More concretely, we can ask if are there  other quantities besides L0 that would form an infinite dimensional commutative algebra  and what their simultaneous spectrum is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Such quantities have been constructed long time  ago by [6, 7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Just as Lm are Fourier modes of the local field T(z), the stress-energy tensor,  we can consider zero Fourier mode of the composite local fields such as (TT)(z) and other  fields of higher dimension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The requirement of commutativity determines this family of  operators uniquely up to overall normalization [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first few members are 1  I1 = T0 = L0 − c  24  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  I3 = (TT)0 = L2  0 + 2  �  m>0  L−mLm − c + 2  12 L0 + c(5c + 22)  2880  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  I5 = (T(TT))0 + c + 2  12 (∂T∂T)0  =  �  m1+m2+m3=0  : Lm1Lm2Lm3 : +  �  m>0  �c + 11  6  m2 − 1 − c  4  �  L−mLm  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  + 3  2  �  m>0  L1−2mL2m−1 − c + 4  8  L2  0 + (c + 2)(3c + 20)  576  L0 − c(3c + 14)(7c + 68)  290304  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Classical limit  Before proceeding, it is useful to mention the classical limit of this con-  struction which is well known in the context of the KdV integrable hierarchy [9, 10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Con-  sider a second order ordinary differential operators of the form  L2 ≡ ∂2  x + u(x)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  which is just the one-dimensional Schrödinger operator with potential −u(x)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One may ask  if there are any deformations of u(x) which do not change the spectrum of the Schödinger  operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Clearly one such example is the rigid translation, but in fact there are infinitely  many other deformations preserving the spectrum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These deformations are organized in the  form of the KdV hierarchy of partial differential equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first non-trivial of these is  4∂tu = 6u∂xu + ∂3  xu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  As easily shown in the theory of integrable hierarchies, given a potential −u(x), its arbitrary  finite time evolution according to (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6) has the same spectrum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There exist infinitely many  such differential equations forming so-called KdV hierarchy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All these flows commute with  each other and are isospectral, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  preserve the spectrum of our Schrödinger operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  1Here the double dots denote the oscillator ordering where Fourier modes Lm with larger m are on the  right.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The discussion of conformal normal ordering and its relation to Fourier modes is summarized in  appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  2u(x) should be chosen from a suitable class of functions, for example periodic functions or functions  rapidly decaying at infinity, but for our purposes this choice is not relevant as the discussion is mostly  algebraic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 2 –  Furthermore, one can think of the space of potentials as being a Hamiltonian system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For  this one introduces a Poisson bracket on the space of potentials  {u(x), u(y)} = −∂3  xδ(x − y) − 4u(x)∂xδ(x − y) − 2∂xu(x)δ(x − y)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  and finds that the equations of KdV hierarchy are generated by Hamiltonians which are  integrals of local densities such as  H1 = 1  2  �  u(x)dx  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  H3 = 1  8  �  u(x)2dx.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  These two Hamiltonians generate the rigid translations and the flow of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6) in the sense  that  {H1, u(x)} = ∂xu(x)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  {H3, u(x)} = ∂tu(x)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  and similarly for all higher equations of KdV hierarchy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since all KdV flows are Hamil-  tonian flows, the Hamiltonians themselves are conserved quantities, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' they are spectral  invariants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Now we see how this classical story parallels the discussion of conserved quan-  tities in Virasoro algebra (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The Poisson bracket (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7) written in terms of the Fourier  modes of u(x) is the classical version (c → ∞ limit) of Virasoro algebra (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1) and the  quantum conserved quantities correspond classically to KdV Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The study of  spectra of Ij is therefore the quantum analogue of the problem of isospectral deformations  of one-dimensional Schrödinger potentials and its associated classical KdV hierarchy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Spectrum and BLZ Bethe ansatz equations  Despite their natural definition and  universal appearance in all 2d CFTs, the simulaneous diagonalization of this collection  of conserved quantities is notoriously difficult.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since in irreducible representations of the  Virasoro algebra the L0 eigenspaces are finite-dimensional, the diagonalization of Ij is in  principle reduced to a diagonalization of a finite dimensional matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' What is missing are  simple closed-form formulas for their joint spectra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A significant progress in this direction  was achieved in a series of papers [8, 11, 12] where the authors used the connection of Vira-  soro algebra to classical KdV hierarchy of differential equations and constructed quantum  analogues of the monodromy matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Traces of these are generating functions of both  local and non-local conserved quantities associated to Virasoro algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These generat-  ing functions satisfy non-trivial functional equations (such as the analogue of Baxter’s TQ  relations) as well as non-linear integral equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The next important development happened in the context of ODE/IM correspondence  [13, 14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The authors noticed that the same functional equations found earlier by BLZ  in the context of Virasoro algebra were appearing in the context of ordinary differential  equations and their spectral and monodromy data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First, the discussion was focused on the  lowest weight state of the Virasoro representation, but in [15] BLZ managed to generalize  this correspondence to arbitrary excited states in Virasoro representations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The resulting  – 3 –  prescription for diagonalizing higher conserved charges in the representations of Virasoro  algebra is as follows: we start with the second order differential operator  − ∂2  z + ϵ2(∆ + ϵ2  4 − 1  2)  z2  +  1 − �M  j=1 γj  z  +  M  �  j=1  �  2  (z − zj)2 +  γj  z − zj  �  + λzϵ2−2,  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  where ∆ is the conformal dimension of the primary, ϵ is Nekrasov-like parameter parametriz-  ing the central charge,  c = 13 − 6(ϵ2 + ϵ−2)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  and λ, zj and γj are so far free parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The coefficient of z−1 is chosen for convenience  by rescaling the z coordinate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For generic values of ∆ and ϵ we have a differential operator  with irregular singularities at z = 0 and at z = ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To describe the Virasoro excited states  at level M (in other words L0 eigensubspace with eigenvalue ∆ + M), one allows for M  additional regular singular points z = zj such that the monodromy of the solutions around  these singular points is trivial (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  zj are apparent singularities and we can write two  linearly independent Frobenius solutions around z = zj of exactly the same form as around  any regular point).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The requirement of absence of monodromy at these M points for all λ  determines all γj and further imposes M algebraic equations that need to be satisfied by  M parameters zj,  �  k̸=j  zj(ϵ4z2  j − (ϵ2 − 2)(2ϵ2 + 1)zjzk + (ϵ2 − 1)(ϵ2 − 2)z2  k)  (zj − zk)3  = (1 − ϵ2)zj − ϵ4∆.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  Generically there are as many solutions of these equations as there are partitions of M  [16–18] which agrees with the number of states in generic Virasoro representation at weight  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This gives a nice particle-like interpretation of the states in Virasoro representations:  we can think of states at level M as describing states of M indistinguishable particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Each  particle has associated zj ∈ C and the equations (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) can be thought of as being Bethe  equations describing allowed collections of Bethe roots zj corresponding to quantum states,  analogously to the situation in XXX spin chain or other quantum mechanical integrable  models with finite number of degrees of freedom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All the local higher spin charges are in  turn determined as symmetric polynomials of Bethe roots, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  I1 ⇝ ∆ + M − c  24  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  I3 ⇝ (∆ + M)2 + (ϵ2 − 2)(2ϵ2 − 1)  4ϵ2  (∆ + M) − 4(ϵ2 − 1)  ϵ4  M  �  j=1  zj + c(5c + 22)  2880  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  I5 ⇝ (∆ + M)3 + 6ϵ4 − 17ϵ2 + 6  8ϵ2  (∆ + M)2 − 12(ϵ2 − 1)(ϵ2 + 2)  ϵ4(3ϵ2 + 2)  (∆ + M)  �  j  zj  + (ϵ2 − 2)(2ϵ2 − 1)(18ϵ4 − 59ϵ2 + 18)  192ϵ4  (∆ + M) + 24(ϵ2 − 1)2  ϵ6(3ϵ2 + 2)  �  j  z2  j  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  − (ϵ2 − 1)(ϵ2 + 2)(6ϵ4 − 17ϵ2 + 2)  2ϵ6(3ϵ2 + 2)  �  j  zj − c(3c + 14)(7c + 68)  290304  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 4 –  Despite the fact that Bethe equations (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) can be considered as solution to the original  problem of diagonalizing the local higher spin charges Ij, they have their drawbacks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First  of all, the Virasoro algebra is a rank 2 member of a larger family of vertex operator algebras,  so called WN algebras, all of which can be embedded in two-parametric family called W∞  [19–21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The representation theory of W∞ simplifies considerably if we add additional  Heisenberg algebra �  u(1), resulting in algebra called W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The bases of representation  spaces of W1+∞ are labeled by combinatorial objects such as N-tuples of Young diagrams  or 3d Young diagrams (plane partitions).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is not obvious from the structure of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) how  to generalize these to other WN algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In [22] the construction of monodromy matrices  and Q-operators was generalized to W3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In [23] the authors considered the generalization  of system (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) based on work of Feigin-Frenkel [24] whose general construction allows in  principle to write the analogue of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) for all N > 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But all these systems of Bethe  equations become increasingly complicated as the rank increases and in particular at fixed  level the number of unknowns and equations increases with the rank N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore, they  do not manifest the discrete symmetries (in particular triality symmetry) of the algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Litvinov’s Bethe ansatz equations  In this work we consider another system of Bethe  ansatz equations introduced in [25],  q  N  �  l=1  xj + al − ϵ3  xj + al  �  k̸=j  (xj − xk + ϵ1)(xj − xk + ϵ2)(xj − xk + ϵ3)  (xj − xk − ϵ1)(xj − xk − ϵ2)(xj − xk − ϵ3) = 1,  j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  Here ϵj parameters are Nekrasov-like parameters parametrizing the rank and central charge  of W∞ algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Parameters aj on the other hand parametrize the weights of the lowest  weight vector (generalizing ∆ in the case of Virasoro).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Finally, q is a deformation parameter  to be discussed later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are several important differences between (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) and (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  First of all, the interaction between individual Bethe roots in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) is additive while in  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18) this is controlled by  ϕ(x) = (x + ϵ1)(x + ϵ2)(x + ϵ3)  (x − ϵ1)(x − ϵ2)(x − ϵ3)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  which is the structure constant of W1+∞ [26, 27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It has also a natural interpretation of a  scattering phase (see for instance the TBA equations for elliptic Calogero-Moser system of  [28]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first product in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18) controls interaction of Bethe roots with background fields  which in our situation are just the lowest weights of W1+∞ representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A new ingredient is the twist parameter q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It can be interpreted in several ways and has  an important rôle in the following.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From point of view of the representation theory, it con-  trols which infinite dimensional abelian subalgebra of W1+∞ we are diagonalizing, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' which  integrable structure we are considering.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For generic values of q the associated Hamiltonians  are those of intermediate long wave equation and its hierarchy [25, 29–33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The limits q → 0  and q → ∞ correspond to Yangian limits (Benjamin-Ono limits), where the diagonalized  abelian subalgebra is the abelian subalgebra manifest in the Yangian presentation of the  algebra [26, 27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The advantage of this subalgebra is that it is easily diagonalized in terms  – 5 –  Figure 1: R-matrix as a defect (blue) coupling two chiral CFTs, the quantum space (left) is  considered to be on a cylinder while the auxiliary space (right) is torus with shape controlled  by parameter q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The family of Hamiltonians acting on the cylinder on the left is controlled  by the shape of the auxiliary torus on the right.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In our construction, the torus comes with  a choice of a cycle, so it makes sense to talk about thick or thin torus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' By a thin torus we  mean a torus glued from a long cylinder equipped with a cycle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The limits of infinitely thick  or thin torus correspond to Yangian-Benjamin-Ono family (glued from a long cylidner) or  Korteweg–De Vries-Kadomtsev–Petviashvili-Bazhanov-Lukyanov-Zamolodchikov family of  Hamiltonians (glued from a short cylinder).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For generic shapes q we get Hamiltonians from  the family of intermediate long wave equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  of combinatorics of Young diagrams (or plane partitions).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is reflected in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18) by the  fact that q → 0 or q → ∞ limit Bethe roots become zeros of numerators or denominators,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Litvinov’s Bethe equations factorize into linear factors and can be easily solved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Disad-  vantage of the Yangian limit is the fact that the higher conserved quantities are non-local  from the CFT point of view, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' they cannot be written as zero Fourier modes of local  currents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To diagonalize the local charges (quantum KdV or KP charges studied by BLZ),  one needs to consider the limit q → 1 which is however very singular.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One of the aims of  this article is to study concretely the behaviour of various quantities in the local limit and  extract information about local charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are other rôles of parameter q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From spin  chain point of view it is simply the twist parameter, controlling shape of the auxiliary space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Concretely, q parametrizes the complex structure of the auxiliary Riemann surface which  is introduced as a regulator of the trace over auxiliary space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This trace would otherwise  not be defined since in our situation the auxiliary space is infinite dimensional.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Finally,  from point of view of numerical solution of equations (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18), q appears as a very natural  homotopy parameter, allowing us to smoothly connect the solvable Yangian limit with the  physically interesting local BLZ limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As we will see, there is very interesting analytic  structure of solutions of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18) over q-plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 6 –  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Summary of the paper  The aim of this work is to apply the procedure of algebraic Bethe ansatz [34, 35] to explicitly  construct first few commuting quantum ILW Hamiltonians, study their spectra in terms of  Litvinov’s Bethe ansatz equations as well as their local q → 1 limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  More concretely, we start from Maulik-Okounkov instanton R-matrix [36–39] for a  pair of free bosons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Working in the large spectral parameter expansion, we fuse these  and calculate first few coefficients of the universal R-matrix, which has the form of the  exponential of integral of local currents in two copies of W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the next step we  specialize the auxiliary space to be the one of single free boson and calculate the trace to get  the transfer matrix acting in the quantum space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the free boson Fock space is infinite  dimensional, we have to regularize the trace.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Following [25], we choose the regulator to be  of the form qL0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This choice effectively puts the auxiliary boson on a torus with modular  parameter q, without spoiling the commutativity of the resulting ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This  setup is illustrated in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The left part of the diagram represents the quantum space  which we identify with a conformal field theory with W1+∞ symmetry living on a cylinder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The right part of the diagram shows the auxiliary space which is a torus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will mostly  restrict to the situation where the theory associated with the auxiliary space is a single free  boson.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The R-matrix is an operator acting on product of both spaces so we can think of  it as being a codimension 2 defect inserted along the product of two blue circles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is  somewhat similar to the construction of quantum transfer matrices in [8, 11, 12], but in  their setup, the auxiliary space is a finite dimensional representation space of underlying  quantum group Uq(sl(2)), 3 while in our setup the underlying symmetry algebra is W1+∞  or equivalently the Yangian of �gl(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Technically the hardest part of the article is the evaluation of the trace.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We calculated  first five non-trivial ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Assuming validity of Litvinov’s conjectured Bethe  ansatz equations, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the fact that the spectra of ILW Hamiltonians can be written in terms  of symmetric functions of solutions of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18), we are able to determine exact expressions  for eigenvalues of all five ILW Hamiltonians that we found.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These are in turn matched to a  conjectural formula analogous to a formula by Feigin, Jimbo, Miwa and Mukhin [40] that  was proven in the related context of quantum toroidal algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Our expressions for the  spectra of first five ILW Hamiltonians perfectly agree with the conjectural formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the next part, we study carefully the local (q → 1) BLZ/KdV/KP limit of Bethe  ansatz equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This limit is quite singular, because it is exactly the limit of removal of  the regulator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Both ILW Hamiltonians as well as most solutions of Bethe ansatz equations  become singular in this limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  But surprisingly the singularities in Bethe roots can be  associated to excitations of Heisenberg subalgebra of W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The remaining Bethe roots,  finite in q → 1 limit, are associated to more interesting W∞ subalgebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Using our explicit  expressions for first five ILW Hamiltonians, we show how to disentangle the Heisenberg  part from W∞ conserved quantities and give formulas for conserved quantities I2 and I3  3The authors of [8, 11, 12] also consider infinite dimensional auxiliary vector spaces but these do not  have an interpretation of another copy of QFT - these representations can be thought of as highest weight  representations of continuous spin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 7 –  generalizing (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) from Virasoro algebra to W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We conclude by some examples of solutions of Bethe ansatz equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We study both  analytically and numerically the solutions at lower levels in Lee-Yang model (chiral algebra  associated to (A1, A2) Argyres-Douglas model) and in the first unitary minimal W4 model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The analytic structure of Bethe roots as functions of parameter q is extremely rich, as it  captures the representation theory of WN minimal models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  2  Instanton R-matrix  In this section, we will review the construction of Maulik and Okounkov’s instanton R-  matrix [36, 38, 39, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will follow the notation and conventions of [39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Consider a  collection of N independent free bosons Jj(z) (ˆgl(1) Heisenberg vertex operator algebras)  with OPE  Jj(z)Jk(w) ∼  δjk  (z − w)2 + reg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  where j or k label the free bosons, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' take values from 1 to N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To each of these currents  we associate Miura operator  α0∂z + Jj(z)  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  where α0 is a fixed complex number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Composing these first order differential operators  results in Nth order differential operator with coefficients that are local fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are  no ordering ambiguities when we multiply the fields since the Jj(z) coming from different  factors of the product commute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The subalgebra generated by the coefficients of Nth order  differential operator turns out to be closed under operator product expansions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  It is a  product of diagonal ˆgl(1) Heisenberg algebra with WN algebra and the construction we  just reviewed is the simplest free field representation of WN [42–44].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the case of N = 2  (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' starting with just two free bosons) the algebra W2 goes under the name of Virasoro  algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Decoupling the diagonal ˆgl(1) current in this case gives a representation of Virasoro  algebra in terms of one free boson J1 − J2 and in the classical limit this is the well-known  Miura transformation (studied originally in the context of KdV hierarchy).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Note that the composition of elementary Miura operators (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) to construct WN algebra  is analogous to construction of gl(M) Yangian from its level 1 representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Fusing N  of these using the Yangian coproduct, we get level N representation of gl(M) Yangian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In  the context of integrable spin chains N is related to the length of the spin chain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In CFT  N is related to the maximal spin of the generating fields of the algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Yangian of gl(M)  is obtained by fusion of general number of level 1 representation (corresponding to spin  chains of arbitrary length) and the analogous notion in CFT is the algebra W1+∞ which  has generators of all spins [19, 20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All WN algebras can be obtained by truncation from  W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The construction goes through essentially unmodified if we replace ˆgl(1) by ˆgl(M)  in which case we obtain a matrix-valued W1+∞ algebra (Yangian of affine gl(M)) [45, 46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In order to construct WN generators as differential polynomials in ˆgl(1) currents Jj,  we need to multiply the elementary operators (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) in certain order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The resulting algebra  is independent of the order, but the way it sits in the Fock space of N free bosons depends  on the order of the elementary Miura factors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Maulik-Okounkov R-matrix is the similarity  – 8 –  transformation that connects these embeddings [36].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since any permutation is a composition  of transpositions, it is enough to study the case of N = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this case, R is an operator  acting on product of two ˆgl(1) Fock spaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Up to an overall normalization, it is uniquely  defined by the property  R(α0∂ + J1)(α0∂ + J2) = (α0∂ + J2)(α0∂ + J1)R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  Commuting the derivatives to the right, we see that this is equivalent to  R(α2  0∂2+α0(J1+J2)∂+(J1J2)+α0J′  2)R−1 = (α2  0∂2+α0(J1+J2)∂+(J1J2)+α0J′  1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  Since R does not depend on the coordinate of the local fields (it is expressible purely in  terms of their Fourier modes), in order for this equation to be satisfied the coefficients of  each power of ∂ must be equal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The coefficients of ∂2 agree trivially.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the coefficients  of ∂1 we see that R must commute with the total current J1 + J2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This means that it has  to be constructed out of modes of the difference current  J− = α0(J1 − J2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  The remaining restriction therefore comes from the equality of coefficients of ∂0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Written  in terms of J− (and simplifying using the commutativity with J1 + J2), this amounts to  R  �1  2(J−J−) + α2  0∂J−  �  R−1 = 1  2(J−J−) − α2  0∂J−  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  This is the main equation that defines Maulik-Okounkov R-matrix in terms of local fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Given an action of R on the vacuum of J− Fock space (which determines the overall  normalization of R), this equation determines level by level the action of R on all other  states in the Fock space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  One can also solve the equation (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6) perturbatively in large spectral parameter [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In CFT, the rôles of the spectral parameter are the zero modes of the ˆgl(1) currents [39]  which are central.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For this reason, in [38, 39] the zero mode of J− was treated differently  than the remaining modes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Various terms in perturbative expansion of R were written in  terms of oscillators not involving the zero mode of J−.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the analysis that we will do  here we will keep this zero mode.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, we will introduce the spectral parameter u by  performing a constant shift (which is an automorphism of the Heisenberg algebra)  J−(z) → J−(z) + α0u.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  This introduces certain redundancy which we can use as consistency check of our calcula-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The equation (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6) becomes  R  �  α0uJ− + 1  2(J−J−) + α2  0∂J−  �  =  �  α0uJ− + 1  2(J−J−) − α2  0∂J−  �  R  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  This is the equation that we can solve perturbatively at large u.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It turns out that the large  u expansion of R simplifies if we take a logarithm of R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We therefore write  R(u) = exp  �  r(1)  α0u + r(2)  α2  0u2 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  ≡ exp r(u)  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  – 9 –  Here r(j) turn out to be zero modes of certain local currents constructed of J− (this is the  reason for taking the logarithm of R) [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  At leading order u0 we need to solve  �  r(1), J−  �  + 2α2  0∂J− = 0  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  whose solution is  r(1) = −1  2(J−J−)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  This is a unique solution that is a zero mode of a local operator of dimension 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we relax  the requirement of dimension 2, we can add to r(1) a linear combination of the zero mode  of J− and of the identity operator (which are both central).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This freedom in turn can be  absorbed into u-dependent normalization of R which is not fixed by (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  At next order u−1 we have  �  r(2), J−  �  + 1  2  �  r(1)2, J−  �  +  �  r(1), 1  2(J−J−)  �  + α2  0  �  r(1), ∂J−  �  = 0  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  which simplifies to  �  r(2), J−  �  +  �  r(1), 1  2(J−J−)  �  = 0  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  with solution  r(2) = 1  6(J−(J−J−))0  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  (which is again unique zero mode of a local field up to addition of a constant or of the zero  mode of J−).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that all terms in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12) that were not commutators canceled.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This had  to be the case as follows from the ad-exp identity  e[r,·]  �  α0uJ− + 1  2(J−J−) + α2  0∂J−  �  = α0uJ− + 1  2(J−J−) − α2  0∂J−.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  Order u−2 terms of this equation are  �  r(3), J−  �  + 1  2  �  r(1),  �  r(2), J−  ��  + 1  2  �  r(2),  �  r(1), J−  ��  + 1  6  �  r(1),  �  r(1),  �  r(1), J−  ���  +  +  �  r(2), 1  2(J−J−) + α2  0∂J−  �  + 1  2  �  r(1),  �  r(1), 1  2(J−J−) + α2  0∂J−  ��  = 0  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  whose unique local solution is  r(3) = − 1  12(J−(J−(J−J−)))0 + α2  0(1 + 2α2  0)  12  (∂J−∂J−)0  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  up to addition of central terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Writing this in terms of creation-annihilation normal order  (using expressions in appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1), we find  r(3) = − 1  12 : J4  − :0 +α2  0  12 : J2  − :0 − α4  0  144 + α2  0(1 + 2α2  0)  12  : ∂J−∂J− :0 −α2  0(1 + 2α2  0)  12  α2  0  60 (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  – 10 –  in agreement with mode expansions (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44) of [39]4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Employing the identity (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15), we can find perturbative solution for r(j) much more  efficiently than by manipulating the mode expansions as was done by hand in [38, 39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All  we need to do is to calculate multiple commutators of zero mode of a local operator with  another local operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As discussed in appendix A, this in turn amounts to taking the first  order pole of OPE between two local operators which can be done very quickly using the  package OPEdefs by Thielemans [47].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this way, the r(j) can be found to rather high order  (j ∼ 20) in few seconds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first few of these expressions are given in appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note  that since in terms of Fourier modes on cylinder the zero mode of total derivative vanishes,  there is an ambiguity in writing r(j) as zero modes of local operators – although the zero  mode is well-defined and uniquely determined, the local operator is not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The most important property of R whose construction we just reviewed is the fact that  it satisfies the Yang-Baxter equation  R12(u1 − u2)R13(u1 − u3)R23(u2 − u3) = R23(u2 − u3)R13(u1 − u3)R12(u1 − u2) (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  In order to understand origin of this equation, we need to consider three Fock spaces and  two ways how to change the order 123 → 321.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The operator constructed out of Fourier  modes of fields that is exponential of local field is unique up to central terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore,  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19) has to hold up to possible difference in normalization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  As usual in the context of quantum integrability, once we have a solution of Yang-  Baxter equation (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19), the procedure of algebraic Bethe ansatz can be immediately applied  to construct commuting Hamiltonians and study their spectrum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is what we will do  in the following sections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  3  Universal R-matrix  In this section we would like to find an expression for R for representations not restricted  to Yangian level 1 (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' we are interested in fields of spin greater than 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In order to do  that, we will take the elementary level one R-matrices defined in the previous section and  fuse them N times in the left factor and ¯N times in the right factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Having an expression  for general N and ¯N, this is equivalent to knowing a universal R-matrix of W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This  R-matrix will satisfy Drinfeľd’s relations  R∆(x)R−1 = ∆op(x)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  (∆ ⊗ 1)(R) = R13R23  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  (1 ⊗ ∆)(R) = R13R12  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  as we will verify perturbatively in large central charge expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here x is any local field  (or its Fourier mode) and ∆(x) is the coproduct [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  4This agrees with (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47) if the parentheses in [39] are understood as creation-annihilation normal order-  ing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 11 –  R1¯1  R2¯1  R3¯1  R4¯1  R5¯1  R1¯2  R2¯2  R3¯2  R4¯2  R5¯2  R1¯3  R2¯3  R3¯3  R4¯3  R5¯3  R1¯4  R2¯4  R3¯4  R4¯4  R5¯4  Figure 2: Illustration of the fusion of elementary R-matrices for (N, ¯N) = (5, 4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We  should multiply Rj¯k starting from the upper left corner and proceeding all the way to the  lower right corner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the elementary factors that are neither on same row nor on the  same column commute, the multiplication column-by-column or row-by-row gives the same  answer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Universal R-matrix from fusion  We start with N + ¯N copies of ˆgl(1) Fock space, labeled by Hj, j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , N and H¯k,  k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , ¯N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will denote the elementary R-matrix acting on Hj ⊗ H¯k by Rj¯k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  fused R-matrix is then given by a product of N × ¯N terms  R ≡ R1 ¯  NR2 ¯  N · · · RN ¯  NR1N−1 · · · RNN−1 · · · R1¯2 · · · RN¯2R1¯1R2¯1 · · · RN¯1  =  N  �  −−→  j=1  ¯  N  �  ←−−  k=1  Rj¯k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  The factors corresponding to Hj are multiplied from left to right while the factors corre-  sponding to H¯k are multiplied in the opposite direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is necessary in order for the  result to be expressible in terms of WN × W ¯  N generators (this is also consistent with the  difference between Drinfeľd’s relations (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) and (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is illustrated in Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We  multiply the individual factors starting from the upper left corner and proceeding all the  way to the lower right corner, with every step going either right or down.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All the factors  appearing to the left or above any given elementary R-matrix must appear in the product  on the left.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is the only restriction on the order of factors in the product and any two  orders satisfying this restriction are equivalent due to commutativity of Rj¯k which sit on  different rows and columns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Since every elementary R-matrix is of the form of an exponential of a zero mode of  local fields, and since commutator of two zero modes of local fields is again a zero mode of  a local field, Baker-Campbell-Hausdorff formula guarantees that the fused R-matrix is of  – 12 –  this form as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore, we can use the Baker-Campbell-Hausdorff formula to find  the large spectral parameter expansion of the fused R-matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will denote the fused  R-matrix by R(u) (in contrast to R(u) which denotes the elementary R-matrix).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The large  spectral charge expansion of R(u) is of the form  R(u) = exp  �  r(1)  u  + r(2)  u2 + r(3)  u3 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  ≡ exp r(u)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  Unlike in the case of (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9) here we absorb the powers of α0 into coefficients r(j) (the former  was kept to be compatible with conventions of [39]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As before, each r(j) will be zero mode  of a local field of engineering dimension j + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore, this local field is determined  uniquely up to total derivatives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In order to determine the coefficients r(j) in the large spectral charge expansion of  R(u), we use the Baker-Campbell-Hausdorff formula generalized to an arbitrary number of  factors in the product, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the expansion  log(eX1eX2 · · · eXN ) =  �  j  Xj + 1  2  �  j<k  [Xj, Xk]  + 1  12  �  j<k  ([Xj, [Xj, Xk]] + [[Xj, Xk] , Xk])  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  + 1  6  �  j<k<l  ([Xj, [Xk, Xl]] + [[Xj, Xk] , Xl]) + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  and similar but more complicated expressions at higher orders.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is important that every-  thing is expressed in terms of repeated commutators, so in particular assuming that the  elementary R-matrix was of the form of exponential of zero mode of a local field, the same  will be automatically true for R(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For the leading coefficient, we find  r(1) = −α0  2  �  (j,¯j)  ((Jj − J¯j)(Jj − J¯j))0  = −α0 ¯N  2  �  j  (JjJj)0 − α0N  2  �  ¯j  (J¯jJ¯j)0 + α0  �  j,¯j  (JjJ¯j)0  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  where j and ¯j are considered as independent summation variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Using the expressions  for free field representations of WN generators (for example section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 in [20]), we can  identify this with  r(1) = −α0 ¯N  �  −U2 + 1  2(U1U1)  �  0 − α0N  �  − ¯U2 + 1  2( ¯U1 ¯U1)  �  0 + α0(U1 ¯U1)0  = −α0 ¯NT0 − α0N ¯T0 + α0(U1 ¯U1)0  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  where  T = −U2 + 1  2(U1U1) + (N − 1)α0  2  ∂U1  = 1  2  �  j  (JjJj) + α0  2  �  j  (N + 1 − 2j)∂Jj  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  – 13 –  is the total stress-energy tensor of the left copy of ˆgl(1) × WN and similarly for ¯T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here  and in the following we use bars for all quantities associated to the right factor, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the  local fields Uj satisfy the OPEs of ˆgl(1) × WN with parameter α0 [20] while the fields ¯Uj  satisfy OPEs of an independent ˆgl(1) × W ¯  N with parameter α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that by construction  both algebras have the same value of the parameter α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is equivalent to having same  Kapustin-Witten parameter ψ in the notation of [48, 49] or in the language of [26, 27] having  the same Nekrasov-like parameters (h1, h2, h3) up to an overall scale.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This constraint reflects  the fact that the fusion operation using W1+∞ coproduct exists at fixed value of α0 while  acting additively in N [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Although the fusion construction that we are discussing is assuming N and ¯N to be  positive integers, the resulting expressions are written as expressions in terms of local fields  with coefficients that are rational functions of N, ¯N and α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can therefore interpret  them as expressions in W∞, without any restrictions on N and ¯N [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the following, we  will freely tranition between WN and W∞ picture, depending on what is more convenient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  At the next order, it follows from the Baker-Campbell-Hausdorff formula that  r(2) = 1  α2  0  �  j,¯j  r(2)  (j,¯j) +  1  2α2  0  �  (j,¯j)<(k,¯k)  �  r(1)  (j,¯j), r(1)  (k,¯k)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  Here the notation (j, ¯j) < (k, ¯k) is related to our fixed order of the vertices in Figure 2, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  we can sum over all pairs that have either (j < k) or (j = k and ¯k < ¯j) – remember the  opposite order of the barred indices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Plugging in the expressions for r(j), this equals  r(2) = α0  6  �  j,¯j  �  (Jj(JjJj)) − 3((JjJj)J¯j) + 3(Jj(J¯jJ¯j)) − (J¯j(J¯jJ¯j))  �  0  + α2  0  8  �  (j,¯j)<(k,¯k)  �  (JjJj) − 2(JjJ¯j) + (J¯jJ¯j)0, (JkJk) − 2(JkJ¯k) + (J¯kJ¯k)0  �  = α0 ¯N  6  �  j  (Jj(JjJj))0 + α2  0 ¯N  2  �  j<k  (∂JjJk)0 − α0N  6  �  ¯j  (J¯j(J¯jJ¯j))0  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  − α2  0N  2  �  ¯j<¯k  (∂J¯jJ¯k)0 − α0  2  �  j,¯j  ((JjJj)J¯j)0 + α0  2  �  j,¯j  (Jj(J¯jJ¯j))0  − α2  0  2  �  j  �  ¯k  ( ¯N + 1 − 2¯k)(∂JjJ¯k)0 + α2  0  2  �  j  (N + 1 − 2j)  �  ¯k  (Jj∂J¯k)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Defining a local spin 3 field  φ3 = U3 − (U1U2) + 1  3(U1(U1U1)) − (N − 2)α0  2  U ′  2  + (N − 1)α0  2  (U ′  1U1) + N2α2  0 − Nα2  0 + 4α2  0 + 2  12  U ′′  1  = 1  3  �  j  (Jj(JjJj)) + α0  2  �  j<k  (∂JjJk − Jj∂Jk)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  + α0  2  �  j  (N + 1 − 2j)(∂JjJj) + 1  6  �  j  ∂2Jj  – 14 –  + α2  0  12  �  j  (3j2 + 3(N + 1 − j)2 − (N + 1)(2N − 1))∂2Jj  we finally find  r(2) = α0 ¯N  2  φ3,0 − α0(T ¯U1)0 + α0(U1 ¯T)0 − α0N  2  ¯φ3,0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  Note that the last two lines in the free field representation of φ3 are total derivatives so they  do not contribute to the zero mode and therefore to r(2), but this choice of φ3 will slightly  simplify the expression for r(3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we require r(j) to be a zero mode of a field of engineering  dimension j + 1, the only ambiguity is in total derivatives, which do not contribute to the  zero mode.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We also see that if we did not choose the order of the barred indices in (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4) to  be the opposite of the order of the unbarred indices, we would not be able to write r(2) in  terms of ˆgl(1) × W ¯  N generators – the sign of  �  ¯j<¯k  ∂J¯jJ¯k  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  would be wrong, and it is the sign of this term that reflects the way we ordered our free  bosons J¯j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The calculation could be alternatively done entirely in terms of oscillators, but such a  calculation is computationally harder (while leading to the same result).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can use the  free field representation and fusion as just described to proceed to higher orders.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this  way we calculated r(3) and r(4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The expressions for these are given in the appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Drinfeľd’s relations I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  It is easy to verify Drinfeľd’s relations (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) and (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3) perturbatively in large u.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the  coproduct is a homomorphism of algebras, we can take the logarithm of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2),  (∆ ⊗ 1)r(u) = log [exp (r13(u)) exp (r23(u))]  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  and apply the BCH formula on the right-hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Expanding at large u, we find for the  first few orders  (∆ ⊗ 1)(r(1)(u)) = r(1)  13 (u) + r(1)  23 (u)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  (∆ ⊗ 1)(r(2)(u)) = r(2)  13 (u) + r(2)  23 (u) + 1  2  �  r(1)  13 (u), r(1)  23 (u)  �  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  (∆ ⊗ 1)(r(3)(u)) = r(3)  13 (u) + r(3)  23 (u) + 1  2  �  r(1)  13 (u), r(2)  23 (u)  �  + 1  2  �  r(2)  13 (u), r(1)  23 (u)  �  + 1  12  �  r(1)  13 (u),  �  r(1)  13 (u), r(1)  23 (u)  ��  + 1  12  ��  r(1)  13 (u), r(1)  23 (u)  �  , r(1)  23 (u)  �  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Unlike in the previous section, here we only need the two-variable BCH formula to  evaluate the right-hand side, but for the left-hand side we need to know the coproduct of  ˆgl(1) × WN generators [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Let us explicitly verify the first of these relations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We need to calculate the coproduct  of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8) in the first factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have (see section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8 in [20])  ∆(N) = N(1) + N(2)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  – 15 –  ∆(U1) = U(1)1 + U(2)1  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  ∆(U2) = U(1)2 + U(2)2 + (U(1)1U(2)1) + α0N(1)∂U(2)1  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  so  ∆(T) = T(1) + T(2) + α0N(2)  2  ∂U(1)1 − α0N(1)  2  ∂U(2)1  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  and  (∆ ⊗ 1)(r(1)(u)) = −α0N(3)∆(T0) − α0∆(N)(T(3))0 + α0(∆(U1)U(3)1)0  = −α0N(3)  �  (T(1))0 + (T(2))0 + α0N(2)  2  (∂U(1)1)0 − α0N(1)  2  (∂U(2)1)0  �  − α0(N(1) + N(2))(T(3))0 + α0(U(1)1U(3)1)0 + α0(U(2)1U(3)1)0  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  while the right-hand side is  r(1)  13 (u) + r(1)  23 (u) = −α0N(3)(T(1))0 − α0N(1)(T(3))0 + α0(U(1)1U(3)1)0  − α0N(3)(T(2))0 − α0N(2)(T(3))0 + α0(U(2)1U(3)1)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  Since the zero mode of a total derivative vanishes, we see that both of these expressions  agree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We may similarly verify these two Drinfeľd’s relations up to order u−4 involving r(4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We calculated these coefficients explicitly by fusing the elementary R-matrices (and explicit  expressions for these are given in appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the formula for comultiplication of  generators of W1+∞ is known [20], we may as well use Drinfeľd’s relations to determine  higher r(j) coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this way we determined r(5) and r(6), but these are too long to list  here (the expression for r(6) has 22 pages in Mathematica).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The calculation using Drinfeľd’s  relations is more efficient way to determine r(j) than using the free field representations as  was done in the previous section, especially because the BCH formula for large number of  variables is complicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Spectral shift and normalization of R(u)  The algebras ˆgl(1) × WN have continuous automorphisms shifting the (central) zero mode  of ˆgl(1) generator by a constant and leaving the WN part intact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the quadratic basis  of generators of the algebra that we are using, the ˆgl(1) and WN factors are mixed, so in  particular all Uj fields transform under this transformation linearly as  Uj → Sγ(Uj) ≡  j  �  k=0  (N − j + 1)k  γk  k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Uj−k  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  where (N)k is the raising factorial (Pochhammer symbol) and γ is a parameter of the  symmetry transformation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Under such transformation of the left sector, the coefficients r(j)  transform as  r(j) →  j−1  �  k=0  �j − 1  k  �  (−γ)kr(j−k) + (−γ)j  j  α0( ¯NU1 − N ¯U1)0 − (−γ)j+1  j(j + 1) α0N ¯N1  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  – 16 –  This is almost equivalent to a shift of the spectral parameter u:  r(u) →  ∞  �  j=1  r(j)  (u + γ)j + log  �  u  u + γ  �  α0( ¯NU1 − N ¯U1)0 +  �  (u + γ) log  �  u  u + γ  �  + γ  �  α0N ¯N  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  The reason why this is not simply translation of u parameter is that in (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5) and in similar  expansion of the elementary R-matrix we chose a specific (unnatural) normalization of  R(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can always rescale R(u) (or shift r(u)) by any central function, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' function of  N, ¯N, α0 and of zero modes of U1 and ¯U1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we define  ˜r(u) ≡ r(u) − log u α0( ¯NU1 − N ¯U1)0 − (u log u − u)α0N ¯N,  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  this object transforms simply under the spectral transformation of the left sector:  ˜r(u) → ˜r(u + γ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  In the following, intermediate calculations with R(u) are simpler, but using ˜R(u) leads to  some simpler results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The translation between them is easy since they are related by an  overall central normalization factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  Drinfeľd’s relations II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We still have not verified Drinfeľd’s relation (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is slightly more subtle because of large  spectral parameter expansion that we are using.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In particular, we calculated the asymptotic  expansion of R(u) as in (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we take equation (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1) literally, the right-hand side as well  as the coproduct on the left-hand side would be u-independent, so the term of order u0  would immediately tell us that the coproduct and its opposite agree which does not make  sense.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In order to make sense of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1) order by order in u, we need to introduce the spectral  parameter u also in the coproduct, analogously to (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, we will consider the  relation in the form  R(u)Su(∆(x))R(u)−1  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='= Su(∆op(x))  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  where Su is the spectral shift by γ = u in the first factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' With no loss of generality we do  not need to do any spectral shift in the second factor, because of the intertwining property  ∆(Sγ(x)) = Sγ( ¯Sγ(∆(x))).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  Returning to (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30), let us see what these equations explicitly imply for fields of lower  dimension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The simplest choice is taking x = U1(z).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For this choice, both coproduct and  the opposite coproduct agree,  ∆(U1) = U1 + ¯U1 = ∆op(U1)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  and  Su(∆(U1)) = U1 + ¯U1 + uN = Su(∆op(U1))  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  so (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30) is in this case equivalent to commutativity of R(u) with the total spin 1 generator  U1 + ¯U1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first non-trivial choice is x = U2(z).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here we have  ∆(U2) = U2 + ¯U2 + (U1 ¯U1) + α0N∂ ¯U1  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  – 17 –  ∆op(U2) = U2 + ¯U2 + (U1 ¯U1) + α0 ¯N∂U1  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  and therefore  Su(∆(U2)) = u2  2 N(N − 1) + u(N − 1)U1 + uN ¯U1 + U2 + ¯U2 + (U1 ¯U1) + α0N∂ ¯U1  Su(∆op(U2)) = u2  2 N(N − 1) + u(N − 1)U1 + uN ¯U1 + U2 + ¯U2 + (U1 ¯U1) + α0 ¯N∂U1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  The identity (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30) with x = U2(z) is therefore equivalent to  R(u)  �  −uU1 + U2 + ¯U2 + (U1 ¯U1) + α0N∂ ¯U1  �  =  =  �  −uU1 + U2 + ¯U2 + (U1 ¯U1) + α0 ¯N∂U1  �  R(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  Using explicit expressions for r(j) given in appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3, we can verify this identity is indeed  satisfied (to the order in large u expansion that we considered).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can similarly verify for  x = U3(z), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' that to order that we calculated R(u) Drinfeľd’s relation (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1) is satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  4  ILW Hamiltonians  We will now use the universal R-matrix to construct commuting Hamiltonians of ILW  hierarchy [25, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Having constructed an R-matrix satisfying the Yang-Baxter equation  with spectral parameter, we can use the standard technology from quantum integrability  to construct an infinite collection of commuting Hamiltonians [34, 35].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  For R-matrices  acting in finite dimensional vector spaces it is enough to take a trace of R-matrix over one  of the factors (usually called the auxiliary space) that it is acting on.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We are left with  one-parametric family (parametrized by spectral parameter u) of operators that act on the  remaining factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These operators commute for different values of u as follows from the  Yang-Baxter equation and therefore we obtain a collection of commuting Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In our setup there is a slight twist to this procedure, because the vector spaces involved  are infinite dimensional.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For this reason the trace is not well-defined and the construction of  the commuting Hamiltonians needs to be modified.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One possibility explored in [38, 39] is to  consider the vacuum-to-vacuum matrix element instead of the trace.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In general it is not true  that taking an arbitrary matrix element would lead to commuting quantities, but for our  choice of R-matrix and the vacuum matrix element this is true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The resulting Hamiltonians,  although non-local from CFT point of view, are related to Yangian generators of the algebra  [26, 39] and have spectrum that is easy to describe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In particular, their spectrum can be  written in terms of combinatorics of partitions or plane partitions (3d Young diagrams).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  There is another possibility of producing commuting Hamiltonians: instead of taking  the trace of R over the auxiliary space, we can take the regularized trace [25, 41], schemat-  ically of the form  Tr  �  q  ¯L0R(u)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  Here ¯L0 is the ‘energy’ acting on the auxiliary space and |q| < 1 is a complex regulator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the q → 1 limit we expect to reduce to the usual (ill-defined) trace.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  On the other  – 18 –  hand, in the limit q → 0 (after appropriate rescaling) only the vacuum-to-vacuum matrix  element contributes and we should obtain the Yangian Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It turns out that  the Hamiltonians constructed using this regularized trace mutually commute for arbitrary  fixed value of q (and for varying value of spectral parameter) and can be identified with  Hamiltonians of quantum ILW hierarchy [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the CFT point of view we are studying  the situation where the right part of R-matrix is inserted along a circle on a torus whose  shape (complex structure) is controlled by q (see Figure 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  As we will see later, the  parameter q enters the Bethe ansatz equations in the same way as the twist parameter in  quantum spin chains, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' controls the twisting that the we can do when we are closing  an open spin chain into a closed one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For general q the Hamiltonians that we obtain are  non-local, but they become local in the (singular) q → 1 limit and as we will see later they  will agree with the local Hamiltonians considered in [8, 14, 22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We will now find explicit expressions for first few ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As usual, the  expressions simplify when we take the logarithm of the generating function of Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In this way, although non-local, the non-locality takes a specific form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From now on we will  restrict to ¯N = 1 so  ¯U1 ≡ ¯J,  ¯Uj = 0, j ≥ 2  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  and the vacuum representation on the right, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the lowest weight vector in the right factor  will satisfy  ¯Jm |0⟩ = 0,  m ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  Different choice of lowest weight vector (in particular ¯J0 eigenvalue) can be related to our  calculation by shift of the spectral parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  For any operator O we will define the normalized expectation value (regularized trace  over the auxiliary space) by  ⟨O⟩q ≡ Trq ¯T0O  Trq ¯T0 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  Note that since the zero mode of the stress-energy tensor ¯L0 on the plane and on the  cylinder ¯T0 differ only by a constant, such a constant would cancel between the numerator  and the denominator so we can equivalently replace ¯T0 by ¯L0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since we are restricting to  ¯N = 1, the Fock space over which we are taking the trace has states labeled by Young  diagrams and ¯L0 simply counts the number of boxes in the corresponding Young diagram.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Therefore, the expectation value can also be written as  ⟨O⟩q =  �  λ q|λ| ⟨¯λ| O |¯λ⟩  �  λ q|λ|  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  The sum is over all Young diagrams λ and |λ| denotes the number of boxes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The Hilbert  space vectors |¯λ⟩ form a basis of the barred (auxiliary) Hilbert space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' By definition, the  expectation value of any constant (or of any operator that acts proportional to the identity  operator in the barred Hilbert space) is the operator itself.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For more interesting example,  let us consider the expectation value of ¯L0:  ⟨¯L0⟩q =  �  λ |λ|q|λ|  �  λ q|λ|  = q∂q log  �  λ  q|λ| = q∂q log  � ∞  �  k=1  1  1 − qk  �  – 19 –  =  ∞  �  k=1  kqk  1 − qk = 1 − E2(q)  24  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  where E2(q) is the second holomorphic Eisenstein series (weight 2 quasi-modular form), see  appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The result is simpler when expressed in terms of cylinder zero mode ¯T0:  ⟨ ¯T0⟩q = ⟨¯L0 − 1  24⟩q = −E2(q)  24  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  We are now ready to evaluate the first ILW Hamiltonians: we define  Hq(u) ≡ ⟨R(u)⟩q  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  as well as the large u expansion of its logarithm  log Hq(u) ≡  ∞  �  j=1  (log Hq)j  uj  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  Since R(u) is itself an exponential of integral of local fields, we are taking here a loga-  rithm of an expectation value of an exponential, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the quantities (log Hq)j will be (non-  commutative) connected expectation values of r(j).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For the first few of these quantities we  find  (log Hq)1 = ⟨r(1)⟩  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  (log Hq)2 = ⟨r(2)⟩ + 1  2  �  ⟨r(1)2⟩ − ⟨r(1)⟩2�  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  (log Hq)3 = ⟨r(3)⟩ + 1  2  �  ⟨r(1)r(2)⟩ − ⟨r(1)⟩⟨r(2)⟩ + ⟨r(2)r(1)⟩ − ⟨r(2)⟩⟨r(1)⟩  �  +  �1  6⟨r(1)3⟩ − 1  4⟨r(1)2⟩⟨r(1)⟩ − 1  4⟨r(1)⟩⟨r(1)2⟩ + 1  3⟨r(1)⟩3  �  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  (log Hq)4 = ⟨r(4)⟩ + 1  2  �  ⟨r(1)r(3)⟩ − ⟨r(1)⟩⟨r(3)⟩ + ⟨r(2)2⟩ − ⟨r(2)⟩2 + ⟨r(3)r(1)⟩ − ⟨r(3)⟩⟨r(1)⟩  �  +  �1  6⟨r(1)2r(2)⟩ − 1  4⟨r(1)2⟩⟨r(2)⟩ − 1  4⟨r(1)⟩⟨r(1)r(2)⟩ + 1  3⟨r(1)⟩2⟨r(2)⟩  �  +  �1  6⟨r(1)r(2)r(1)⟩ − 1  4⟨r(1)r(2)⟩⟨r(1)⟩ − 1  4⟨r(1)⟩⟨r(2)r(1)⟩ + 1  3⟨r(1)⟩⟨r(2)⟩⟨r(1)⟩  �  +  �1  6⟨r(2)r(1)2⟩ − 1  4⟨r(2)r(1)⟩⟨r(1)⟩ − 1  4⟨r(2)⟩⟨r(1)2⟩ + 1  3⟨r(2)⟩⟨r(1)⟩2  �  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  +  � 1  24⟨r(1)4⟩ − 1  12⟨r(1)3⟩⟨r(1)⟩ − 1  12⟨r(1)⟩⟨r(1)3⟩ − 1  8⟨r(1)2⟩2  + 1  6⟨r(1)⟩2⟨r(1)2⟩ + 1  6⟨r(1)⟩⟨r(1)2⟩⟨r(1)⟩ + 1  6⟨r(1)2⟩⟨r(1)⟩2 − 1  4⟨r(1)⟩4�  where we write expectation values ⟨.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='⟩q without the subscript q when this is clear from  the context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As already mentioned, taking these non-commutative connected expectation  values will make the non-localities in (log H)j milder in the sense that will become clearer  as we proceed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 20 –  First ILW Hamiltonian  We can now turn to the first Hamiltonian (log H)1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All we  need to do is to take the expectation value of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8),  (log Hq)1 = ⟨−α0T0 − α0N ¯T0 + α0(U1 ¯U1)0⟩q  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  = −α0T0 − α0N⟨ ¯T0⟩q + α0⟨(U1 ¯U1)0⟩q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  In (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7) we already calculated the expectation value of ¯T0 so it only remains to evaluate the  expectation value of the last term, but this clearly vanishes (because ¯J0 acts as zero and  non-zero mode operators have vanishing expectation values).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We therefore find  (log Hq)1 = −α0T0 + α0NE2  24  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  We see that the first Hamiltonian is up to a constant equal to L0, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the standard (holo-  morphic part of the) Hamiltonian associated to radial quantization in CFT, independently  of q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Only the higher Hamiltonians will have non-trivial q-dependence, the Hamiltonian  L0 is shared by the BLZ, Yangian or the general ILW family of Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The typical  representation spaces are infinite dimensional, but since the higher commuting quantities  commute with L0, the diagonalization of these is reduced to (finite dimensional) eigensub-  spaces of L0 and therefore the diagonalization is effectively a finite dimensional problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Second ILW Hamiltonian  Let us now turn to the second ILW Hamiltonian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  From  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11) we need to evaluate ⟨r(2)⟩ as well as the connected expectation value of r(1)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We  have  ⟨r(2)⟩q =  �α0 ¯N  2  φ3,0 − α0(T ¯U1)0 + α0(U1 ¯T)0 − α0N  2  ¯φ3,0  �  q  = α0  2 φ3,0 + α0U1,0⟨ ¯T0⟩q − α0N  6  ⟨( ¯J( ¯J ¯J))0⟩q  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  = α0  2 φ3,0 − α0E2  24 U1,0  where we used the fact that the expectation values of objects involving odd powers of ¯J  vanish by Z2 symmetry (this would not be the case if we did not restrict to auxiliary  representation with ¯J0 ∼ 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For the connected expectation value of r(1)2 we have  ⟨r(1)2⟩q − ⟨r(1)⟩2  q =  ��  −α0T0 − α0N ¯T0 + α0(U1 ¯U1)0  �2�  q −  �  −α0T0 − α0N ¯T0 + α0(U1 ¯U1)0  �2  q  = +α2  0N2⟨ ¯T 2  0 ⟩c − α2  0⟨T0(U1 ¯U1)0⟩c − α2  0⟨(U1 ¯U1)0T0⟩c  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  − α2  0N⟨ ¯T0(U1 ¯U1)0⟩c − α2  0N⟨(U1 ¯U1)0 ¯T0⟩c + α2  0⟨(U1 ¯U1)2  0⟩c  Here we introduced a notation for connected expectation values,  ⟨AB⟩c ≡ ⟨AB⟩q − ⟨A⟩q⟨B⟩q  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  Using the calculations and formulas for expectation values in appendix C, we can simplify  this to  ⟨r(1)2⟩q − ⟨r(1)⟩2  q = α2  0N2 E4 − E2  2  288  + α2  0  ��  m>0  m1 + qm  1 − qm U1,−mU1,m + N  �  m>0  m2qm  1 − qm  �  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  – 21 –  Notice that most terms disappeared when we take the connected expectation values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Adding  this result together with the expression for the expectation value of r(2), we finally find  (log Hq)2 = α0  2  �  U3 − (U1U2) + 1  3(U1(U1U1))  �  0  + α2  0  2  �  m>0  m1 + qm  1 − qm U1,−mU1,m  − α0E2  24 U1,0 + α2  0N2 E4 − E2  2  576  + α2  0N  2  �  m>0  m2qm  1 − qm  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  On the first line we see the first non-trivial ILW Hamiltonian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is a sum of two terms,  first being local while the second one involving  �  m>0  m1 + qm  1 − qm U1,−mU1,m ≡  �  m>0  (dm + d−m)U1,−mU1,m  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  which cannot be written as a zero mode of a local operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here we use the modified  derivative  dm ≡  m  1 − qm .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  The non-locality of the product of two U1(z) fields is controlled by q-dependent  (dm + d−m) = m1 + qm  1 − qm = m coth  �m log q  2  �  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  which at fixed q is an even function of m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the limit q → 1 we have  m1 + qm  1 − qm ∼  2  1 − q − 1 + m2 − 1  6  (1 − q)1 + O((1 − q)2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  We see that every coefficient of (1−q)j is a polynomial in m2, so all the coefficients in 1−q  expansion of (log Hq)2 are zero modes of local operators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, in the limit  q → 0 we have instead  m1 + qm  1 − qm → |m|  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  so in this limit (log Hq)2 cannot be written as a zero mode of a local operator (one would  need to use the Hilbert transform to produce the absolute value of the Fourier mode |m|).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We find a non-locality typical of Benjamin-Ono hierarchy which also appears in the affine  Yangian context [27, 50].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the limit q → ∞ we find the same absolute value of the  mode number (which corresponds to charge conjugate Yangian Hamiltonians).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is very  interesting that the parameter q which in our construction appears geometrically as a shape  (complex structure) of the auxiliary torus naturally controls the non-locality of the higher  Hamiltonians and in particular interpolates between the local limit at q = 1 (which is  expected to be related to BLZ-like integrals of motion) and non-local limit of the Benjamin-  Ono / Yangian type (at q = 0 and q → ∞).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For q equal to a root of unity we get local  twisted Hamiltonians as will be illustrated later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For other values of q, we get generically  the intermediate long wave Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There exists also an elliptic generalization of this  type of non-local interaction terms, see for instance [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 22 –  In a similar manner, we can find explicit expressions for higher order ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Since the calculations get very long very quickly, we only determine (log Hq)3, (log Hq)4  and (log Hq)5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Explicit expressions for first two of these as well as some details of the  calculation are given in the appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Spectral translation  It is useful to verify how do the ILW Hamiltonians that we found  transform under the shift of the spectral parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The transformation of (log H)j under  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25) is inherited from that of R-matrix (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26),  (log Hq)j →  j−1  �  k=0  �j − 1  k  �  (−γ)k(log Hq)j−k + (−γ)j  j  α0U1,0 − (−γ)j+1  j(j + 1) Nα0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  More explicitly, it is easy to check using the explicit forms of the Hamiltonians that  (log Hq)1 → (log Hq)1 − γα0U1 − γ2  2 Nα0  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  (log Hq)2 → (log Hq)2 − γ(log Hq)1 + γ2  2 α0U1,0 + γ3  6 Nα0  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  (log Hq)3 → (log Hq)3 − 2γ(log Hq)2 + γ2(log Hq)1 − γ3  3 α0U1,0 − γ4  12α0N  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  (log Hq)4 → (log Hq)4 − 3γ(log Hq)3 + 3γ2(log Hq)2 − γ3(log Hq)1  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  + γ4  4 α0U1,0 + γ5  20α0N  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  where we used the transformation properties  U1,0 → U1,0 + γN  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  Tm → Tm + γU1,m + γ2 N  2 δm,0  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  φ3,m → φ3,m + 2γTm + γ2U1,m + γ3 N  3 δm,0  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  φ4,0 → φ4,0 − 3γφ3,0 − 3γ2T0 − γ3U1,0 − γ4 N  4  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  φ5,0 → φ5,0 − 4γφ4,0 + 6γ2φ3,0 + 4γ3T0 + γ4U1,0 + γ5 N  5 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  5  Spectrum and Bethe equations  After having constructed the ILW Hamiltonians, we can now study their spectra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will  proceed in few steps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First of all, since we are normalizing the R-matrices as in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9) and  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5), the lowest weight vector (vacuum) eigenvalue of R on the cylinder is non-trivial,  capturing the higher spin Casimir charges of the zero modes of the local fields, so we first  determine these.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Afterwards, we determine the spectrum of operators obtained by taking  the vacuum matrix element on the left or on the right side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The resulting operators are  Yangian Hamiltonians, so they can be diagonalized explicitly in terms of combinatorics of  partitions (or plane partitions).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Their spectrum will give us on one hand the ground state  eigenvalue of ILW Hamiltonians and on the other hand the q → 0 limit of their spectrum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 23 –  Finally, we diagonalize the general q-dependent ILW Hamiltonians that we determined  explicitly in the previous section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will parametrize their eigenvalues in terms of solutions  of Bethe ansatz equations of Litvinov [25] and compare the result with Yangian version of a  formula derived by Feigin-Jimbo-Miwa-Mukhin in the context of quantum toroidal algebra  [40, 51].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Normalization and higher Casimir charges  Using the formula (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22), it is easy to evaluate the vacuum expectation values of r(j).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  first few values are  ⟨a| r(1) |a⟩ = α2  0  12 − α2  0a2  2  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  ⟨a| r(2) |a⟩ = −α3  0a  12 + α3  0a3  6  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  ⟨a| r(3) |a⟩ = −α4  0(3 + α2  0)  360  + α4  0a2  12  − α4  0a4  12  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  ⟨a| r(4) |a⟩ = α5  0(3 + α2  0)a  120  − α5  0a3  12  + α5  0a5  20  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  ⟨a| r(5) |a⟩ = α6  0(5 + 5α2  0 + α4  0)  1260  − α6  0(3 + α2  0)a2  60  + α6  0a4  12  − α6  0a6  30  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  where |a⟩ is the lowest weight vector with respect to J− with zero mode eigenvalue α0a (so  eigenvalue a of J1, see (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The a-dependence is completely determined from the spectral  translation (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29) so we may focus on the case of a = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this case, the coefficients of  even powers of u vanish and for the remaining ones we have  ⟨0| r(2l−1) |0⟩ =  l−1  �  k=0  B2l × (2l − k − 2)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='α4l−2k−2  0  2l × k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (2l − 2k − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  This means that the vacuum eigenvalue of r(u) has an asymptotic expansion  ⟨0| r(u) |0⟩ =  ∞  �  l=1  l−1  �  k=0  B2l × (2l − k − 2)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='α4l−2k−2  0  2l × k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (2l − 2k − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  1  (α0u)2l−1  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  The internal sum can be evaluated if we introduce the Nekrasov-like parameters [26, 27]  ϵ3 = α0,  ϵ1 + ϵ2 + ϵ3 = 0,  ϵ1ϵ2 = −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  We have  l−1  �  k=0  (2l − 1)(2l − k − 2)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='α2l−1−2k  0  k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (2l − 2k − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  = −ϵ2l−1  1  − ϵ2l−1  2  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  so as asymptotic series at large u,  ⟨0| r(u) |0⟩ = −  ∞  �  l=1  B2l  2l(2l − 1)  ��ϵ1  u  �2l−1  +  �ϵ2  u  �2l−1�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  – 24 –  This asympotic expansion captures all the higher Casimir charges of the vacuum state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To  proceed, it is useful to consider ˜r defined in (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28) which includes zero mode of spin 0 and  spin 1 operators and transforms nicely under spectral translation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have  ⟨0| ˜r(u) |0⟩ = −α0(u log u − u) −  ∞  �  l=1  B2l  2l(2l − 1)  ��ϵ1  u  �2l−1  +  �ϵ2  u  �2l−1�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  This is very reminiscent of the asymptotic expansion of Γ function, the Stirling formula  log Γ(z) ∼  �  z − 1  2  �  log z − z + 1  2 log(2π) +  ∞  �  j=1  B2j  2j(2j − 1)z2j−1  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  so  ⟨0| ˜r(u) |0⟩ ∼ − log Γ  � u  ϵ1  �  − log Γ  � u  ϵ2  �  +  � u  ϵ1  �  log 1  ϵ1  +  � u  ϵ2  �  log 1  ϵ2  − 1  2 log u  ϵ1  − 1  2 log u  ϵ2  + log(2π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  Since we calculated the R-matrix perturbatively in large u expansion and the asymptotic  series for gamma function at infinity is not convergent (due to infinite sequence of poles at  negative integers), strictly speaking the normalization of R that we used is not well-defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  But this is easy to fix: we can just choose different normalization of R, for example the non-  perturbative completion in terms of gamma functions as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13) or alternatively we can  normalize R such that the vacuum expectation value is unity, as was done in [38, 39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For  our purposes these issues are not relevant since they affect only the overall normalization  factor, the ratios of matrix elements of R between any two states (of definite L0 level) are  given by rational functions of the spectral parameter so there is no issue of convergence  here (see the next paragraph or [39] where some of these matrix elements are evaluated).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Spectrum of ILW Hamiltonians at q → 0  In the limit q → 0 the ILW Hamiltonians reduce to Yangian Hamiltonians [39, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  spectrum of these has nice combinatorial description in terms of Young diagrams or their  generalizations (N-tuples of these or plane partitions with various asymptotics).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At lower  levels, the eigenvalues can be calculated as exact functions of the spectral parameter u  directly from the definition of the R-matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Let us illustrate this on an example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  elementary R-matrix at level 1 acts as  R(u)J−1 |a, ¯a⟩ =  u + a − ¯a  u + a − ¯a + ϵ3  ECas(u)J−1 |a, ¯a⟩ +  ϵ3  u + a − ¯a + ϵ3  ECas(u) ¯J−1 |a, ¯a⟩  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  R(u) ¯J−1 |a, ¯a⟩ =  ϵ3  u + a − ¯a + ϵ3  ECas(u)J−1 |a, ¯a⟩ +  u + a − ¯a  u + a − ¯a + ϵ3  ECas(u) ¯J−1 |a, ¯a⟩  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  as immediately follows from (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8) [39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here a is the lowest weight eigenvalue of J0 and  ¯a is the lowest weight eigenvalue of ¯J0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' ECas(u) is the eigenvalue of R(u) acting on the  – 25 –  lowest weight state |a, ¯a⟩ (the normalization factor).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the limit q → 0 instead of taking  the normalized trace over the right Hilbert space we simply take the vacuum expectation  value on the right.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, on level 1 in the case of N = 1 = ¯N (and ¯a = 0) we have  Hq=0(u)J−1 |a⟩ =  u + a  u + a + ϵ3  ECas(u)J−1 |a⟩ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  A similar calculation at level 2 shows that the eigenvalues of Hq=0(u) at level 2 are  (u + a)(u + a − ϵ1)  (u + a + ϵ3)(u + a − ϵ1 + ϵ3)ECas(u),  (u + a)(u + a − ϵ2)  (u + a + ϵ3)(u + a − ϵ2 + ϵ3)ECas(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  This calculation can be performed also for general values of integers N and ¯N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At level 1  we have N eigenvalues  ECas(u) ×  ¯  N  �  l=1  u + ak − ¯al  u + ak − ¯al + ϵ3  ,  k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  (corresponding to a single box inserted at u = −ak, k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' N) and similarly at level 2  we have N eigenvalues  ECas(u) ×  ¯  N  �  l=1  (u + ak − ¯al)(u + ak − ¯al − ϵ1)  (u + ak − ¯al + ϵ3)(u + ak − ¯al − ϵ1 + ϵ3),  k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' N,  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  N eigenvalues  ECas(u) ×  ¯  N  �  l=1  (u + ak − ¯al)(u + ak − ¯al − ϵ2)  (u + ak − ¯al + ϵ3)(u + ak − ¯al − ϵ2 + ϵ3),  k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' N,  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  and N(N − 1)/2 eigenvalues  ECas(u) ×  ¯  N  �  l=1  (u + ak1 − ¯al)(u + ak2 − ¯al)  (u + ak1 − ¯al + ϵ3)(u + ak2 − ¯al + ϵ3),  1 ≤ k1 < k2 ≤ N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  The general form of the eigenvalues should be clear: a general state in the Fock space  of N free bosons is labeled by N-tuple of Young diagrams λ(k), k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Each box of  each Young diagram has an associated Bethe root  x = −ak + ϵ1c1(□) + ϵ2c2(□) ≡ −ak + ϵ□  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  where cj(□) are the cartesian coordinates of the box of the Young diagram λ(k), starting  with the first box at coordinates (0, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  The eigenvalues of Hq=0(u) acting on a state  5A better and more symmetric way of writing this would be to consider the Young diagram lying in 1−2  plane of three-dimensional space and write the corresponding Bethe root as −ak+ϵ1c1(□)+ϵ2c2(□)+ϵ3c3(□).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Here c3(□) is the same for all boxes of the Young diagram (since it lies in 1 − 2 plane) and it is natural to  choose the coordinates of the first box to be either (0, 0, 0) or (1, 1, 1) which does not affect the associated  Bethe roots due to the identity ϵ1 + ϵ2 + ϵ3 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 26 –  |λ(1), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , λ(N)⟩ which has associated Bethe roots xℓ, ℓ = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M where M = |λ(1)| + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' +  |λ(N)| is the total number of boxes is  Hq=0(u) |λ(1), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , λ(N)⟩ = ECas(u)  M  �  ℓ=1  ¯  N  �  k=1  u − xℓ − ¯ak  u − xℓ − ¯ak + ϵ3  |λ(1), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , λ(N)⟩ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  In the previous example at level 2, we had N states with Young diagram  in the k-th  layer, k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , N, another N states with Young diagram  in the k-th layer, k = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , N  and finally N(N−1)/2 states with two Young diagrams  , one in the k1-th layer and another  in the k2-th layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  For later purposes, it will be convenient to write the spectrum of (log Hq=0)j in terms  of symmetric polynomials in Bethe roots (specializing again to ¯N = 1 and ¯a = 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In order  to do that, we just need to take the logarithm of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23) and extract the corresponding  coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We find  (log Hq=0) → log ECas(u) +  M  �  ℓ=1  log  �  u − xℓ  u − xℓ + ϵ3  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  ≃ log ECas(u) +  ∞  �  j=1  1  juj  �j−1  �  k=0  (−1)j−k  �j  k  �  pkϵj−k  3  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  where  pj =  M  �  ℓ=1  xj  ℓ  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  are the Newton power sum polynomials of the Bethe roots and p0 ≡ M = �  j |λ(j)|, the  total number of Bethe roots (which is the level of the corresponding state).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Explicitly,  (log Hq=0)1 → (log Hq=0)1,hw − ϵ3p0  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  (log Hq=0)2 → (log Hq=0)2,hw − ϵ3p1 + ϵ2  3  2 p0  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  (log Hq=0)3 → (log Hq=0)3,hw − ϵ3p2 + ϵ2  3p1 − ϵ3  3  3 p0  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  (log Hq=0)4 → (log Hq=0)4,hw − ϵ3p3 + 3  2ϵ2  3p2 − ϵ3  3p1 + ϵ4  3  4 p0  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  In particular, the Hamiltonians extracted from the logarithm of Hq=0 are linear functions  of the Newton sums pk with coefficients that are independent of N and of lowest weight  charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The dependence on N and on the lowest weight charges comes both from the  lowest weight state contribution as well as from the explicit dependence of Bethe roots on  N and on the lowest weight charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The linearity of these charges in pj is special to q = 0  limit of the ILW Hamiltonians and will not survive the deformation to q → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  With the choice of normalization of R that we are using here, the contribution from  the Casimir charges can be obtained from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7) and we find  (log Hq=0)1,hw = α0  �  u2 − u2  1  2 + N  12  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  – 27 –  (log Hq=0)2,hw = α0  2  �  u3 − u1u2 + u3  1  3 − u1  6  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  (log Hq=0)3,hw = α0  3  �  u4 − u1u3 − u2  2  2 + u2  1u2 − u4  1  4 − u2  2 + u2  1  4 − N(3 + α2  0)  120  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  (log Hq=0)4,hw = α0  4  �  u5 − u1u4 − u2u3 + u2  1u3 + u1u2  2 − u3  1u2 + u5  1  5  − u3 + u1u2 − u3  1  3 + (3 + α2  0)u1  30  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Ground state eigenvalue of ILW Hamiltonians  We can next use the knowledge of the spectrum of Yangian Hamiltonians to determine  the lowest weight state eigenvalue of Hq for q ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Similarly to the discussion in the  previous section, if we take the vacuum-to-vacuum matrix element on the left and allow for  an arbitrary ¯N = 1 state on the right, we find eigenvalues  ¯H¯q=0(u) |¯λ⟩ = ECas(u)  �  □∈λ  N  �  j=1  u + aj − ¯a − ϵ□  u + aj − ¯a − ϵ□ + ϵ3  |¯λ⟩  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  were λ runs over all Young diagrams (states of the right Fock space).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, the lowest  weight state eigenvalue of Hq is  ⟨{aj}| Hq(u) |{aj}⟩ = ECas(u)  �  λ q|λ| ×  �  λ  q|λ| �  □∈λ  N  �  j=1  u + aj − ϵ□  u + aj − ϵ□ + ϵ3  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  where we put ¯a = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Writing this in the form  ⟨{aj}| log Hq(u) |{aj}⟩ = log ECas(u) + log  �  exp  �  □∈λ  N  �  j=1  log  u + aj − ϵ□  u + aj − ϵ□ + ϵ3  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  The second term on the right-hand side can be Taylor expanded at large u as  log  �  exp  ∞  �  k=1  1  kuk  k  �  l=1  k−l  �  m=0  (−1)l+mk!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='ϵl  3  ��N  j=1 am  j  � ��  □∈λ ϵk−l−m  □  �  l!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (k − l − m)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='38)  This is of the form of the logarithm of the exponential of the expectation value of an  expression bilinear in power sums of Bethe roots and power sums of zero modes aj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As  such, its large u expansion coefficients are determined in terms of connected expectation  values of these Newton polynomials.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Denoting the sum of k-th powers of Bethe roots by  Ok =  �  □∈λ  ϵk  □,  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='39)  we find the large u expansion of the vacuum eigenvalue of ILW Hamiltonians to be  log ECas(u) + log  �  exp  ∞  �  k=1  1  kuk  k  �  l=1  k−l  �  m=0  (−1)l+mk!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='ϵl  3  ��N  j=1 am  j  �  l!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (k − l − m)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Ok−l−m  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='40)  – 28 –  For first few Hamiltonians, this is explicitly  (log Hq)′  1,hw = −α0N⟨O0⟩  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='41)  (log Hq)′  2,hw = −α0  2  �  2N⟨O1⟩ − α0N2⟨O2  0⟩c − (α0N + 2u1)⟨O0⟩  �  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='42)  (log Hq)′  3,hw = −α0  6  �  6N⟨O2⟩ − 6α0N2⟨O0O1⟩c + α2  0N3⟨O3  0⟩c  − 6(2u1 + α0N)⟨O1⟩ + 3α0N(2u1 + α0N)⟨O2  0⟩c  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='43)  + 2(3u2  1 − 6u2 + 3α0u1 + α2  0N)⟨O0⟩  �  (log Hq)′  4,hw = −α0  24  �  24N⟨O3⟩ − 24α0N2⟨O0O2⟩c − 12α0N2⟨O2  1⟩c  + 12α2  0N3⟨O2  0O1⟩c − α3  0N4⟨O4  0⟩c + 36α0N(2u1 + α0N)⟨O0O1⟩c  − 6α2  0N2(2u1 + α0N)⟨O3  0⟩c − 36(2u1 + α0N)⟨O2⟩  + 24(3u2  1 − 6u2 + 3α0u1 + α2  0N)⟨O1⟩  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44)  − α0(12u2  1 + 24Nu2  1 − 48Nu2 + 36α0Nu1 + 11α2  0N2)⟨O2  0⟩c  − 6(4u3  1 − 12u1u2 + 12u3 + 6α0u2  1 − 12α0u2 + 4α2  0u1 + Nα3  0)⟨O0⟩  �  where we did not yet add the Casimir contribution (that is the reason for putting a prime  on the left-hand side).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In order to compare with the explicit expressions for (log Hq)j, we  need to evaluate the expectation values such as  ⟨O0⟩ =  �  m>0  d−m = 1 − E2  24  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45)  ⟨O1⟩ = α0  2  �  m>0  (1 − dm + d−m)d−m = α0(1 − E2)  48  − α0  2  �  k>0  k2qk  1 − qk  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='46)  ⟨O2  0⟩c =  �  m>0  dmd−m = E4 − E2  2  288  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47)  as well as higher ones whose expressions are longer so they are collected in appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Using these, we finally find the prediction for eigenvalues of ILW Hamiltonian acting on the  lowest weight state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first two are  (log Hq)1,hw = −α0  �  −u2 + u2  1  2 − N  24  �  + α0NE2  24  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48)  (log Hq)2,hw = α0  2  �  u3 − u1u2 + 1  3u3  1 − u1  12  �  − α0E2  24 u1  + α2  0N2 E4 − E2  2  576  + α2  0N  2  �  m>0  m2qm  1 − qm  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='49)  and the expressions for (log Hq)3,hw and (log Hq)4,hw are given in appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is easy  to see that both ways of calculating these expectation values lead to the same result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  Spectrum of (log Hq)j and Bethe ansatz  According to conjecture of Litvinov, the ILW Hamiltonians that we have constructed can  be diagonalized by solving the Bethe ansatz equations [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' More concretely, to describe  – 29 –  the joint eigenspectrum at Virasoro level M, consider the following system of M algebraic  equations for M unknown Bethe roots xj, j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M  q  N  �  l=1  xj + al − ϵ3  xj + al  �  k̸=j  (xj − xk + ϵ1)(xj − xk + ϵ2)(xj − xk + ϵ3)  (xj − xk − ϵ1)(xj − xk − ϵ2)(xj − xk − ϵ3) = 1,  j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50)  or more concisely  qA(xj)  �  k̸=j  ϕ(xj − xk) = 1,  j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='51)  where  ϕ(u) = (u + ϵ1)(u + ϵ2)(u + ϵ3)  (u − ϵ1)(u − ϵ2)(u − ϵ3)  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52)  is the structure function of W1+∞ and  A(u) =  N  �  l=1  xj + al − ϵ3  xj + al  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='53)  captures the information about the higher spin charges of the lowest weight vector of the  representation (primary).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' 6  From the point of view of W1+∞, these Bethe ansatz equations are very natural: the  product over roots describes interaction between pairs of Bethe roots and is controlled by  the unique structure constant of W1+∞ [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first product encoding the information  about higher spin charges of the lowest weight state of the representation corresponds from  the point of view of Bethe ansatz equations to an interaction of Bethe roots with external  fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Each (physical) solution of BAE is associated to a eigenstate of ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The solution is given by M complex Bethe roots xj, j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M and eigenvalues of all  (log Hq)k are given by symmetric polynomials in xj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  At q = 0, we can explicitly solve these Bethe ansatz equations for any given M and  the Bethe roots can be combinatorially associated to boxes of Young diagrams as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Similar situation happens for q → ∞ but apart from these special values of q, we can solve  the equations only numerically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In terms of these Bethe roots, the eigenvalues of the first  ILW Hamiltonians are given by  (log Hq)1 → −α0p0 + (log Hq)1,hw  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54)  (log Hq)2 → −α0p1 + α2  0  2 p0 + (log Hq)2,hw  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='55)  (log Hq)3 → −α0p2 + α2  0p1 − α0(1 + 4α2  0)  12  p0 + α0E2  12 p0 + (log Hq)3,hw  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='56)  6For concreteness A(u) was written with Y00N truncation of W1+∞ in mind in terms of the corresponding  Coulomb parametres aj (these are the zero modes of free fields in the usual free field representation of Y00N).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  For such representations and generic aj the representation spaces are N-tuples of Young diagrams stacked  along the 3rd direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can replace A(u) by a product of such functions to parametrize the lowest  weight charges of YN1N2N3 algebra (see [52] for more details) or consider more general rational function  with value 1 at u → ∞ to get more general quasi-finite representations of the algebra [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Representations  of this kind have the property that there are only finite number of states at every Virasoro level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 30 –  (log Hq)4 → −α0p3 + 3α2  0  2 p2 − α0(1 + 4α2  0)  4  p1 + α2  0(1 + 2α2  0)  8  p0  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='57)  + α0E2  4  p1 − α2  0E2  8  p0 + α2  0N E4 − E2  2  144  p0 + 3α2  0  �  m>0  m2qm  1 − qm p0 + (log Hq)4,hw  (log Hq)5 → −α0p4 + 2α2  0p3 − 2α3  0p2 + α4  0p1 − α5  0  5 p0 − 12α0⟨O0⟩p2 − 24α0⟨O1⟩p1  + 24α2  0⟨O0⟩p1 − 12α0⟨O2⟩p0 + 24α2  0⟨O1⟩p0 − 2α0(1 + 7α2  0)⟨O0⟩p0  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='58)  + 6Nα2  0⟨O2  0⟩cp1 − 2α2  0u1⟨O2  0⟩cp0 + 8Nα2  0⟨O0O1⟩cp0 − 7Nα3  0⟨O2  0⟩cp0  − N2α3  0(⟨O3  0⟩ − 3⟨O2  0⟩⟨O0⟩ + 2⟨O0⟩3) p0 + (log Hq)5,hw  These expressions were obtained by explicit numerical diagonalization at lower levels as  well as by using the q → 0 limit where the spectrum is known.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The formulas are also  constrained by requiring compatibility with the spectral shift.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that although all these  expressions are at most linear in pj, at order u−6 terms such as ⟨O2  0⟩c p2  0 are expected  to appear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The coefficients of the symmetric polynomials in Bethe roots have explicit  dependence on the twist parameter q via transcendental functions such as the Eisenstein  series Ej.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the explicit form of ILW Hamiltonians we see that the coefficients of these  transcendental functions multiply operators that are expressible in terms of lower degree  ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In other words, by taking a suitable triangular linear combination of  ILW Hamiltonians we can eliminate these transcendental terms and we end up with ILW  Hamiltonians which involve only rational functions of q and whose spectrum is given by  symmetric polynomials in Bethe roots without any additional explicit q-dependence (all  q-dependence comes from q-dependence of Bethe roots themselves).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  Feigin-Jimbo-Miwa-Mukhin formula  Based on the result of these calculations, we will now conjecture a formula for eigenvalues of  the generating function Hq(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The result is in the form of a rational limit of an analogous  result proven by Feigin, Jimbo, Miwa and Mukhin in [40, 51] in the related q-deformed  context of quantum toroidal gl(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We look for the eigenvalues of the generating function Hq(u) in the form  Hq(u) → N  �  λ  q|λ|  M  �  i=1  g(u, xi)  �  □∈λ  h(u, ϵ□)  M  �  i=1  �  □∈λ  f(u, xi, ϵ□).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59)  where N is an overall q- and x-independent normalization prefactor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Now we can use the  two Yangian limits that we studied previously to put restrictions on functions g and h: first  of all, if there are no Bethe roots (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the Virasoro level M = 0), we should reproduce the  lowest weight charges that we calculated in section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In particular, we need  ECas(u)  �  λ q|λ| ×  �  λ  q|λ| �  □∈λ  N  �  j=1  u + aj − ϵ□  u + aj − ϵ□ + ϵ3  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='= N  �  λ  q|λ| �  □∈λ  h(u, ϵ□)  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='60)  from where we see that we need to identify  N = ECas(u)  �  λ q|λ|  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='61)  – 31 –  as well as  h(u, ϵ□) =  N  �  i=1  u + ai − ϵ□  u + ai − ϵ□ + ϵ3  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='62)  The second restriction comes from the q → 0 limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this limit, only the vacuum state  λ = ∅ contributes to the right-hand side of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59) while the left-hand side is given by (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Bethe roots are in this case given as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22) so we have  M  �  i=1  g(u, xi) !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='=  M  �  i=1  u − xi  u − xi + ϵ3  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='63)  or  g(u, xi) =  u − xi  u − xi + ϵ3  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='64)  Finally, it remains to identify the function f(u, xi, ϵ□).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Let us use an ansatz  f(u, xi, ϵ□) = ϕ(u − αxi − βϵ□ − γ)  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='65)  where ϕ(u) is the structure constant of W1+∞ as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Due to restriction ϵ1+ϵ2+ϵ3 = 0,  the Taylor series of log ϕ(u) at u → ∞ starts at order u−4, so the constants α, β and γ can  be fixed by comparing the spectrum with that of (log Hq)4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This determines these to be  α = 1,  β = 1,  γ = −α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='66)  Therefore, the spectrum of the generating function of ILW Hamiltonians Hq(u) is given by  Hq(u) → ECas(u)  �  λ q|λ|  M  �  i=1  u − xi  u − xi + ϵ3  �  λ  q|λ| �  □∈λ  N  �  i=1  u + ai − ϵ□  u + ai − ϵ□ + ϵ3  M  �  i=1  �  □∈λ  ϕ(u−xi −ϵ□ +ϵ3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='67)  which is a rational analogue of a formula by Feigin, Jimbo, Miwa and Mukhin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To summa-  rize, the elements of this formula are  ECas(u) is the normalization factor of the R-matrix  ϵj are the Nekrasov-like parameters of W∞;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' these are determined for example by the  rank N of WN and the central charge (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e by the physical model such as Lee-Yang or  Ising model)  the rational function ϕ(u) is the structure function of W1+∞ which governs the rep-  resentation theory of the algebra;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' it can also be viewed as a scattering phase of the  particles that are described by these Bethe ansatz equations  q is the complex number parametrizing which family of ILW Hamiltonians we are  diagonalizing, different values of q correspond to different integrable structures that  the algebra has;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' from R-matrix point of view it encodes the shape of the auxiliary  torus, from spin chain point of view it is the twist parameter;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' it controls the degree  of non-locality and its inversion corresponds to charge conjugation  – 32 –  the sum over λ represents the trace over the auxiliary space (with states parametrized  by Young diagrams since we focused on ¯N = 1)  ϵ□ are the Yangian Bethe roots associated to the auxiliary sector;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the explicit expres-  sions for these can be read off combinatorially from the associated Young diagram  λ  ai are the parameters parametrizing the lowest weights in the quantum space (Coulomb  parameters in the context of Nekrasov partition functions, external fields from the  point of view of Bethe equations, eigenvalues of zero modes of scalar fields in free field  representations of W1+∞)  xi are the Bethe roots which are determined by solution of Bethe equations;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' these  parameters (and M which is the number of these Bethe roots) are the only parameters  in this formula that depend on the particular eigenstate whose eigenvalues we are  evaluating  Since we used all the Hamiltonians up to (log Hq)4 to fix the parameters in this formula,  we independently verified that also the spectrum of (log Hq)5 agrees with the prediction  coming from this formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the Yangian limit a convenient generating function of higher spin charges of a state  Λ with associated Bethe roots xj is [26, 27]  ψΛ(u) = A(u)  �  j  ϕ(u − xj).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='68)  If we use the same definition for ψΛ(u) in terms of Bethe roots even for q ̸= 0, we can  interpret the FJMM generating function as a dressed or averaged version of ψΛ(u),  Hq(u)  Hq=0(u) →  1  �  λ q|λ|  �  λ  q|λ| �  □∈λ  ψΛ(u − ϵ□ + ϵ3)  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='69)  =  � �  □∈λ  ψΛ(u − ϵ□ + ϵ3)  �  q  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='70)  where the average is physically the canonical Gibbs ensemble over the auxiliary space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  6  Local limit q → 1  It is interesting to understand what happens in the local limit (q → 1) where the ILW  Hamiltonians reduce to local BLZ/KP-like Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This limit is singular: in the  construction of ILW Hamiltonians we used the parameter q to regularize the trace over the  infinite dimensional auxiliary space which would otherwise not be well-defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The local  limit corresponds to removal of this regulator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore it is not surprising that the ILW  Hamiltonians explicitly depend on q in such a way that they become singular as q → 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  But this is not the only singular behavior that we encounter - clearing the denominators  in the Bethe equations (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50) to make them polynomial shows that in the limit q → 1 the  – 33 –  leading coefficients of the polynomials cancel, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the degree of Bethe equations drops.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As  a consequence of that, some of the Bethe roots blow up in the q → 1 limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  As we will see, in the q → 1 limit the W∞ and Heisenberg factors of W1+∞ algebra  decouple and the divergences of Bethe roots as q → 1 make this decoupling possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It  turns out that the Bethe roots that go to infinity as q → 1 are precisely those that describe  the excitations in the Heisenberg subsector of W1+∞ while the roots that remain finite in the  limit correspond to Bethe roots associated to W∞ subalgebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In particular, the divergence  of Heisenberg Bethe roots guarantees that they decouple from Bethe equations for the  remaining W∞ Bethe roots which is an essential ingredient in the decoupling mechanism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  From point of view of ILW Hamiltonians, for generic q we have one independent conserved  quantity of every spin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, if the Heisenberg and W∞ subalgebras of W1+∞  decouple in q → 1 limit, one can expect two independent conserved quantities of every  spin greater than or equal to 2, one conserved quantity being associated to Heisenberg  subalgebra and the other coming from W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Again, it is the singular behaviour of ILW  integrals of motion as q → 1 that makes it possible to diagonalize all of these quantities,  although naïvely there seem to be twice as many of them as for generic q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  q → 1 limit of (log Hq)2  Numerical as well as analytic solution of Bethe ansatz equations  at lower levels (for examples see the following section) shows the following pattern: first  of all, given a solution of BAE, the individual Bethe roots are either regular in the q → 1  limit or diverge as  x =  C  1 − q + o((1 − q)−1)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  where C is a universal constant, same for all Bethe roots (and independent of the specific  solution of Bethe equations), but depending on the ϵj parameters as well as the function  A(u) parametrizing the lowest weights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore, the number of singular Bethe roots  exactly corresponds to the number of excitations associated to the ˆgl(1) subalgebra of W1+∞  while the remaining Bethe roots that are finite in the limit correspond to W∞ factor of the  algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, all the Bethe roots split into two groups as q → 1, those which remain  finite (W∞ roots) and those that go to infinity (Heisenberg roots).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  This behaviour is consistent with the explicit form of ILW Hamiltonians: consider the  first non-trivial ILW Hamiltonian  A2 ≡ −1  2φ3,0 − α0  2  �  m>0  m1 + qm  1 − qm U1,−mU1,m  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  which is obtained from (log Hq)2 after subtracting the transcendental terms (which are in  this case central).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It has spectrum given by  p1 − α0  2 p0 − 1  2u3 + 1  2u1u2 − u3  1  6 + u1  24 ≡ p1 − α0  2 p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  where hw denotes a constant (central) contribution that can be evaluated by acting with  A2 on the lowest weight vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since φ3,0 is a q-independent operator with finite matrix  elements in representations spaces, the only singular part in the q → 1 limit comes from  – 34 –  the second term,  − α0  2  �  m>0  m1 + qm  1 − qm U1,−mU1,m ∼ − α0  1 − q  �  m>0  U1,−mU1,m + O((1 − q)0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  The coefficient of (1−q)−1 term is up to normalization the (Sugawara) stress-energy tensor  of the Heisenberg subalgebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Inspecting the expression for eigenvalues of A2, we see that  the only possible source of such singular behavior is from the term  p1 =  M  �  j=1  xj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  Therefore, if M∞ out of M Bethe roots are regular while remaining M1 roots have leading  singular behavior of the form  C  1 − q  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  with universal constant C (as we can see from the lower level solutions of the Bethe ansatz  equations), we are lead to identify  C  !' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='= −α0N = ψ0ϵ1ϵ2ϵ3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  For easier comparison, we wrote the value of C in terms of triality and scaling-covariant  parameters [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Here ψ0 is the central element of the Yangian algebra which can be  extracted from the generating function of higher spin charges of the lowest weight state via  A(u) = 1 + ϵ1ϵ2ϵ3  ∞  �  j=0  ψj  uj+1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  This numerical value of C is confirmed by the results of numeric as well as analytic calcu-  lations at lower levels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Since in the q → 1 limit we are diagonalizing both (log Hq)1 (which is the zero mode of  the total W1+∞ stress-energy tensor) as well as the zero mode of the stress-energy tensor  of ˆgl(1) (which as we saw is the dominant term in (log Hq)2 in the q → 1 limit), we see  that among the commuting conserved quantities in the q → 1 limit we have also the zero  mode T (∞)  0  of W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This suggests factorization of ILW conserved quantities in the local  limit into Heisenberg conserved quantities and W∞ conserved quantities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is further  confirmed by studying Bethe equations (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50): since Bethe roots associated to W∞ are  regular in the local limit while those of ˆgl(1) are singular, we see that the contribution of  ˆgl(1) roots decouples from the equations determining W∞ roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is again confirmed  by the numerics [53].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In particular, to each W∞ solution of BAE (which has all Bethe roots  finite) we can associate an infinite set of BAE solutions at higher levels which have the  same collection of finite Bethe roots in the q → 1 limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All of these states correspond to  the same state in W∞ subsector but different state in the ˆgl(1) subsector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 35 –  q → 1 limit of (log Hq)3  In order to extract the next local Hamiltonian, we need to study  the singular behavior of (log Hq)3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that as we see from the lower level examples and  numerics [53], in general the behavior of individual Bethe roots as q → 1 is not simply a  Laurent series in integer powers of (1 − q), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' there are non-trivial monodromies of Bethe  roots around q = 1 (as well as around other points in the q-plane) and we need to use  the Puiseux series (Laurent series in fractional powers of 1 − q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But given any solution  of Bethe equations, the examples indicate that analytic continuation around q = 1 only  permutes Bethe roots of that solution, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the power sum polynomials of Bethe roots of a  solution have no monodromy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is unlike the general situation around other special values  of parameter q where even different solutions mix under the monodromy, so the analytic  continuation around all special points in the q-plane connects different eigenstates of the  ILW Hamiltonians, analogously to the situation in other integrable models [54].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Actually,  as we will see in the examples in the next section, the monodromy seems to connect all  eigenstates at given level, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' there is a single multivalued function of x(q) representing  all the Bethe roots associated to physical solutions of Bethe equations at a given level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The fact that monodromy around q = 1 does not mix different solution is also compatible  with q → 1 expansion of ILW Hamiltonians which after subtraction of transcendental terms  have Laurent expansion in integer powers of (1 − q) (since the matrix elements are rational  functions of q with poles only at roots of unity).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Subtracting the term in (log Hq)3 proportional to E2T0 as well as the central terms, we  see that the operator  A3 ≡ −1  3φ4,0 + α0  2  �  m>0  m(1 + qm)  1 − qm  (U1,−mTm + T−mU1,m)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  − α2  0(N + 2)  12  �  m>0  m2U1,−mU1,m + α2  0N  4  �  m>0  m2(1 + qm)2  (1 − qm)2  U1,−mU1,m  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  has spectrum given by  p2 − α0p1 + 1 + 4α2  0  12  p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  The leading singular behavior of A3 is the quadratic pole (1 − q)−2 with coefficient pro-  portional to the �gl(1) Sugawara Hamiltonian which we already encountered in (log Hq)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Therefore, in order to isolate an interesting higher Hamiltonian from (log Hq)3, we need to  cancel this leading order term by a similar term from A2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, we consider the limit  B3 ≡ lim  q→1  �  (1 − q)A3 + α0NA2  �  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  = −α0N  2  φ3,0 + α0  �  m>0  (U1,−mTm + T−mU1,m) − α2  0N  2  �  m>0  U1,−mU1,m  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  with spectrum given by  lim  q→1  �  (1 − q)p2 − (1 − q)α0p1 + α0Np1 − α2  0N  2  p0  �  + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  – 36 –  By construction, this operator commutes with both T (1)  0  and T (∞)  0  so in particular should  be a sum of a zero mode of spin 3 operator in W∞ and in ˆgl(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is indeed the case: in  terms of Heisenberg and W∞ modes, this operator can be written as  B3 = −α0N  2  W3,0 − α0U1,0T0 + α0  3N (U1(U1U1))0 − α2  0N  4  (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  We used the fact that  �  m>0  (U1,−mTm + T−mU1,m) = (U1T)0 − U1,0T0 + 1  12U1,0  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  and introduced the unique (up to normalization) spin 3 primary field in W∞  W3 = U3 − N − 2  N  (U1U2) + (N − 1)(N − 2)  3N2  (U1(U1U1)) − (N − 2)α0  2  U ′  2  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  + (N − 1)(N − 2)α0  2N  (U ′  1U1) + (N − 1)(N − 2)α2  0  12  U ′′  1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  Let us Taylor expand the power sum polynomials of Bethe roots as  p1 = p1,−1  1 − q + p1,0 + p1,1(1 − q) + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  p2 =  p2,−2  (1 − q)2 + p2,−1  1 − q + p2,0 + p2,1(1 − q) + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  The monodromy properties of Bethe roots around 1 − q as discussed above imply that the  series expansion has only integer powers of 1 − q, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' is a Laurent expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore,  the leading singular behaviour of power sums is determined by (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Plugging this form of  pj into (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14), we find the expansion  p2,−2 + α0Np1,−1  1 − q  + p2,−1 + α0Np1,0 + α2  0N  2  M1 − α2  0N  2  M∞ + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  where we used that p0 ≡ M = M1 + M∞ and  p1,−1 = −α0NM1  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  as follows from (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We see that in order for this quantity to be non-singular as q → 1,  we need to have  p2,−2 = −α0Np1,−1 = (−α0N)2M1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  This condition together with analogous conditions coming from higher conserved quantities  actually imply (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1) (with universal value of C), so we find an a posteriori reason coming  from the representation theory for validity of (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In order to disentangle the spin 3  quantities associated to ˆgl(1) and W∞, we proceed to the next ILW Hamiltonian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 37 –  q → 1 limit of (log Hq)4  By looking at the local expansion of A4 in appendix E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2, we see  that the following combination is finite as q → 1:  B4 ≡ lim  q→1  �  (1 − q)2A4 + α0N(1 − q)A3  �  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  = N2α3  0  2  �  m>0  U1,−mU1,m − α2  0U1,0  �  m>0  U1,−mU1,m  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  − 3  2α2  0  �  m1,m2>0  (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  = −α2  0  2 (U1(U1U1))0 + α2  0U1,0(U1U1)0 + N2α3  0  4  (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  Its spectrum is given in terms of Bethe roots by  B4 ⇝ p3,−2 + Nα0p2,−1 + Nα2  0  2  p1,−1 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  and the finiteness of the limit in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24) requires in addition that  p3,−3 = −Nα0p2,−2 = (−Nα0)3M1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  q → 1 limit of (log Hq)5  Finally, we can have a look at the local limit of (log Hq)5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  quantity that is finite in the local limit is  B5 ≡ (1 − q)2A5 + 7Nα0  3  (1 − q)A4 + 4N2α2  0  3  A3 + N3α3  0  6  A2 − Nα2  0u1  3  A2  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  corresponding to operator  B5 = −4α2  0N2  9  �  W4,0 −  3(N − 3)(α2  0N2 + 3α2  0N − 9)  2N(5α2  0N3 − 5α2  0N − 5N − 17)(T∞T∞)0  �  + α2  0  2N  �  (U1(U1(U1U1)))0 − N(U ′  1U ′  1)0  �  + 2α2  0N  3  T 2  0 − α2  0T0(U1U1)0  + 3α2  0N  2  U1,0W3,0 − α3  0N3  12  W3,0  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  − α2  0  N U1,0(U1(U1U1))0 − 19α3  0N  36  (U1(U1U1))0  + 2α2  0U 2  1,0T0 − α3  0N2  6  U1,0T0 − α2  0N  4  T0  + 4α3  0N  3  U1,0(U1U1)0 + α2  0(36 + 7α2  0N3)  72  (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  It is written manifestly in terms of commuting conserved quantities of W∞ and of the  Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In fact, the operator  S4 ≡ W4,0 −  3(N − 3)(α2  0N2 + 3α2  0N − 9)  2N(5α2  0N3 − 5α2  0N − 5N − 17)(T∞T∞)0  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  – 38 –  is the unique zero mode of spin 4 local field in W∞ commuting in W3,0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here W4 is the  unique spin 4 primary field in W∞ normalized such that  W4 = U4 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  In W∞ we have 4 fields of dimension 4, W4, (T∞T∞), ∂W3 and ∂2T∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The latter two fields  are total derivatives so have vanishing zero modes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The requirement of commutativity with  W3,0 is equivalent to the simple pole of OPE of W3 with our candidate for spin 4 conserved  quantity being a total derivative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have  W3(z)(T∞T∞)(w) ∼ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' + 4(T∞∂W3)(w)  z − w  + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  W3(z)W4(w) ∼ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' + 6(N − 3)(α2  0N2 + 3α2  0N − 9)  N(5α2  0N3 − 5α2  0N − 5N − 17)  (T∞∂W3)(w)  z − w  + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  where we did not write explicitly the regular terms, poles of order higher than one and  operators that are total derivatives (which are in this case fields ∂W5, ∂3W3 and ∂(T∞W3)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We see that indeed the combination (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32) is unique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A similar situation happens with spin 4 quantity in the Heisenberg subalgebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There  are two dimension 4 local fields modulo total derivatives, (U1(U1(U1U1))) and (∂U1∂U1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Their OPE with (U1(U1U1)) is  (U1(U1U1))(z)(U1(U1(U1U1)))(w) ∼ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' +  24N  5(z − w)∂(U1(U1(U1(U1U1))))(w)  + 6N2  z − w(∂3U1(U1U1))(w) + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  (U1(U1U1))(z)(∂U1∂U1)(w) ∼ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' + 12N  z − w(∂U1(∂U1∂U1))(w)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  + 12N  z − w(∂2U1(∂U1U1))(w) +  N2  5(z − w)∂5U1(w) + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  where we listed all the simple poles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first and the last term are obviously total deriva-  tives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore, the identity  (∂U1(∂U1∂U1)) + (∂2U1(∂U1U1)) = 1  2(∂3U1(U1U1)) − 1  2∂(∂2U1(U1U1)) + ∂(∂U1(∂U1U1))  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='38)  implies that the combination  (U1(U1(U1U1)))0 − N(∂U1∂U1)0  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='39)  commutes with (U1(U1U1))0 and this is indeed the combination that appears in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To  summarize, by taking correctly the local limit q → 1 we obtained from (log Hq)5 and lower  order ILW Hamiltonians the quantity B5 in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is a function of conserved quantities  of spin up to 4 both in W∞ and in the Heisenberg subalgebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore, its spectrum  (as follows from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54)-(5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='58)) is given by  B5 ⇝ p4,−2 + 7α0N  3  p3,−1 + 4α2  0N2  3  p2,0 − 2α0p3,−2 − 7α2  0N  2  p2,−1  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='40)  – 39 –  + α3  0N2(N − 8)  6  p1,0 − α2  0N  3  u1p1,0 + α0N(1 + 4α2  0)  12  p1,−1  + α2  0N2(4 + 16α2  0 − 3α2  0N)  36  p0,0 + α3  0N  6  u1p0,0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='41)  The finiteness of the limit in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30) furthermore requires additional two conditions satisfied  by pj,k,  p4,−4 = (−α0N)3p1,−1 = (−α0N)4M1  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='42)  p4,−3 = −7α0N  3  p3,−2 − 4α2  0N2  3  p2,−1 − α2  0N  6  (N(N + 1)α0 − 2u1)p1,−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='43)  In order to isolate the contribution of W∞ conserved charge and Heisenberg conserved  charge, we would need to consider the next quantity, (log Hq)6, but such calculation would  be technically very difficult.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  W∞ conserved charges and Bethe ansatz equations  We can now focus on states  that have no Heisenberg excitations, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' states in W∞ subrepresentations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this case,  all Bethe roots have finite limit as q → 1 so pj,k = 0 for k < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the expression for  eigenvalues of B3 we deduce that the operator W3,0 has spectrum  W3,0 ⇝ −2  �  p1,0 + u1  N M∞  �  + α0M∞ + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44)  Let’s emphasize again that this equation only holds if there are no Heisenberg excitations,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' if all Bethe roots are finite in the local limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It might seem strange at first that the  formula for the spectrum of W3,0 depends on u1 which is the zero mode of the Heisenberg  current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But this is actually needed for consistency: Bethe equations are invariant under  translations of Bethe roots if we simultaneously translate the Coulomb parameters al (this  symmetry is just the spectral shift symmetry), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  xj −→ xj − γ  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45)  al −→ al + γ  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='46)  u1 −→ u1 + Nγ  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47)  is the symmetry of the equations which simply shifts the zero mode of the Heisenberg field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The combination in parentheses in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44) is invariant under these translations as it should  be since the left-hand side does not involve Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we are interested in W∞,  we can always choose the Coulomb parameters in such a way that u1 = 0 and the formula  simplifies further.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Proceeding similarly with spin 4 conserved quantity, we find spectrum  S4 ⇝ −3  �  p2,0 + 2u1  N p1,0 + u2  1  N2 M∞  �  + 3α0  �  p1,0 + u1  N M∞  �  + 3  2N (M2  ∞ + 2∆M∞)  + N3α2  0 − 9Nα2  0 − 3N − 3  8N  M∞ + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48)  – 40 –  Heisenberg conserved charges and Bethe ansatz equations  Let us now turn to  the spectrum of Heisenberg conserved quantities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28) we see that the spectrum of  (U1(U1U1))0 is given in terms of Bethe roots by  (U1(U1U1))0 ⇝ − 2  α2  0  p3,−2 − 2N  α0  p2,−1 − 4u1  α0  p1,−1 − N(N + 1)p1,−1 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='49)  In terms of mode expansion, we have  (U1(U1U1))0 = U 3  1,0 − N  4 U1,0 + 6U1,0  �  m>0  U1,−mU1,m  + 3  �  m1,m2>0  (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50)  The operator on the second line is the cut-and-join operator whose spectrum is known to  be  6N  3  2  �  □∈λ  (x□ − y□)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='51)  where λ is a Young diagram parametrizing an excitation of Heisenberg algebra 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The  prefactor N  3  2 is due to the fact that our normalization of U1 is such that the two-point  function is proportional to N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In order for these two to match, the physical Bethe roots  need to satisfy a non-trivial constraint,  6N  3  2  �  □∈λ  (x□ − y□) = − 2  α2  0  p3,−2 − 2N  α0  p2,−1 + 2u1  α0  p1,−1 − N(N + 1)p1,−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52)  Numerical evidence shows that there is in fact an additional relation  p3,−2 = −2α0Np2,−1 − α0u1p1,−1 + N(N + 1)α2  0  2  p1,−1  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='53)  so assuming this is true in general, we find a constraint  6N  3  2  �  □∈λ  (x□ − y□) = 2N  α0  �  p2,−1 + 2u1  N p1,−1  �  − 2N(N + 1)p1,−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54)  Writing this purely in terms of Bethe ansatz equations in manifestly triality and scaling  invariant way (in particular not restricting to ϵ1ϵ2 = −1), we find a representation-theoretic  restriction on Bethe roots  3  �  □∈λ  (x□ − y□) = −  1  ϵ1ϵ2ϵ3  √ψ0  �  p2,−1 − 2ψ1  ψ0  p1,−1 + 2ψ0ϵ1ϵ2ϵ3p1,−1  �  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='55)  The quantities ψ0 and ψ1 can be read off from the generating function of lowest weight  charges A(u) via (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In terms of α0, N and u1 we have  ψ0 = − N  ϵ1ϵ2  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='56)  7This formula only applies to Heisenberg algebra and should not be confused with the parametrization  of states in W1+∞ in the Yangian limit q → 0 or q → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 41 –  ψ1 = u1  ϵ1ϵ2  + N(N − 1)  2  ϵ3  ϵ1ϵ2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='57)  It is quite interesting how the local behaviour of the Bethe roots around q = 1 encodes  discrete (quantized) quantities such as the eigenvalues of the cut-and-join operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In  particular, although the Bethe ansatz equations are non-linear algebraic equations, there  still exist infinitely many constraints on the coefficients of Puiseux expansion around q → 1  which encode the shape of Young diagram of the associated state of Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Specialization to Virasoro algebra  We can specialize the previous discussion to N =  2 (Virasoro algebra) and compare to results of BLZ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The central charge is conveniently  parametrized by  c = 1 − 6(p′ − p)2  p′p  = 1 − 6α2  0  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='58)  and  ϵ1 =  �  p′  p ,  ϵ2 = −  � p  p′ ,  ϵ3 = −  �  p′  p +  � p  p′ = α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59)  We choose Coulomb parameters a1 and a2 such that u1 = 0 and express them in terms of  conformal dimension ∆ of the primary,  a1 + a2 = 0,  ∆ =  �  a1 + ϵ3  2  � �  a1 − ϵ3  2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='60)  The function capturing the higher spin charges of the primary state is  (u + a1 − ϵ3)(u + a2 − ϵ3)  (u + a1)(u + a2)  −→ (u − ϵ3)2 − ∆ − ϵ3  3  4  u2 − ∆ − ϵ3  3  4  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='61)  It is convenient to shift the Bethe roots according to  xj = yj + ϵ3  2  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='62)  so the Bethe equations (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50) become  q  �  yj − ϵ3  2  �2 − ∆ − ϵ2  3  4  �  yj + ϵ3  2  �2 − ∆ − ϵ2  3  4  �  k̸=j  (yj − yk + ϵ1)(yj − yk + ϵ2)(yj − yk + ϵ3)  (yj − yk − ϵ1)(yj − yk − ϵ2)(yj − yk − ϵ3) = 1,  j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='63)  or  q  �  yj − ϵ3  2  �2 − ∆ − ϵ2  3  4  �  yj + ϵ3  2  �2 − ∆ − ϵ2  3  4  �  k̸=j  �  (yj − yk)2 − ϵ3(yj − yk) − 1  �  (yj − yk + ϵ3)  [(yj − yk)2 + ϵ3(yj − yk) − 1] (yj − yk − ϵ3) = 1,  j = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' , M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='64)  where in the second equation we eliminated ϵ1 and ϵ2 and expressed everything in terms of  ϵ3 = α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These equations have the obvious charge conjugation symmetry (exchanging the  numerators and the denominators)  q → q−1,  yj → −yj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='65)  – 42 –  Specializing to quantum KdV charges at q = 1, we find that the spin 3 charge is  W3,0 ⇝ −2  M  �  j=1  yj  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='66)  which is required to vanish for Virasoro physical states and for spin 4 charge we find instead  S4 ⇝ −3  M  �  j=1  y2  j + 3  4(M2 + 2M∆) + α2  0  8 M − 9  16M + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='67)  This should be compared to formula for spectrum of I3 in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16) where for N = 2 we have  S4 = 1  4I3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='68)  The charge conjugation symmetry flips sign of odd spin generators and keeps the even spin  generators invariant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the case of Virasoro algebra there are no odd spin generators so  Virasoro representations are self-conjugate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The solutions of Bethe equations have to be  self-conjugate, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' given any solution, the Bethe roots can be either zero or come in pairs  of roots differing by a sign.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is consistent with the form of eigenvalues of W3,0 and S4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  As an illustration, at level 1, the unique solution of Bethe equations is  y1 = 0  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='69)  with corresponding S4 eigenvalue  3  2∆ + α2  0  8 + 3  16 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='70)  which agrees with formula (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='67).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At level 2 there are two states, L−2 |∆⟩ and L2  −1 |∆⟩ and  from explicit diagonalization we find that S4 has eigenvalues  3∆ − α2  0  2 + 3  2 ± 3  8  �  32∆ + 4α4  0 + 4α2  0 + 1 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='71)  The solutions of Bethe ansatz equations are given by pairs of roots {y, −y} with y satisfying  8y4 − (1 + 2α2  0)y2 − ∆ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='72)  Solving this biquadratic equation and plugging in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='67), we reproduce exactly (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='71).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Roots of unity and twisted subalgebras  From the explicit expressions for ILW Hamiltonians we see that q = 1 is not the only  singular point in the q-plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In fact, from the term (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22) we see that all the roots of unity  are singular at sufficiently high level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, in the limit of highly excited states, the  interior |q| < 1 of the unit circle and its exterior |q| > 1 are separated by a dense set of  singular points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 43 –  Let us choose q0 to be a primitive K-th root of unity (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' for q0 = 1 we have K = 1,  for q0 = −1 we have K = 2, for q0 = ±i we have K = 4 etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=').' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The ILW Hamiltonian A2  has simple pole at q = q0 with residue  lim  q→q0(q − q0)A2(q) = α0q0  �  m>0  U1,−KmU1,Km.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='73)  Some of the Bethe roots again diverge in the q → q0 limit with leading singular behaviour  x ∼  ˜C  q − q0  + o((q − q0)−1)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='74)  where the coefficient ˜C is a common value for all of the singular Bethe roots analogously  to the situation at q → 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Let us assume analogously to q → 1 case that there is no  monodromy around q ∼ q0 after we take power sums of Bethe roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The spectrum of  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='73) is given by  α0q0NK|λ|  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='75)  where λ is the Young diagram labeling a state in the Hilbert space associated to K-twisted  Heisenberg algebra (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Heisenberg algebra generated by Fourier modes U1,Km, m ∈ Z).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In our conventions we label the state U1,−K |0⟩ by  with single box.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Comparing this  spectrum with the spectrum of A2 (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3) which is  ˜C ˜  M1,  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='76)  where ˜  M1 is the number of singular Bethe roots, we see that the constant ˜C has to be equal  to  ˜C = α0q0N K|λ|  ˜  M1  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='77)  The numerical data at lower levels indicate that every box of λ corresponds to K singular  roots, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the fraction in equation above is equal to unity and that the constant ˜C is  ˜C = q0α0N  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='78)  which is up to a phase the same result as we found in the local limit q → 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This value is  confirmed by the numerical experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It would be very interesting to see which other  Hamiltonians can be extracted from higher Aj and whether twisting by K happens only in  the Heisenberg subsector or affects also the rest of the algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  7  Examples of solutions  Let us discuss some concrete examples of solutions of Bethe ansatz equations (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Lee-Yang model  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Argyres-Douglas minimal models  We will start with the Lee-Yang model with c = − 22  5 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This model is special in several  ways.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is at the same time a minimal model of Virasoro algebra as well as of W3 algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 44 –  Figure 3: Periodic plane partition corre-  sponding to ∆ = 0 primary of Lee-Yang  model  Figure 4: Periodic plane partition cor-  responding to ∆ = 0 primary of Ising  model  Figure 5: Periodic plane partition cor-  responding to ∆ = − 1  5 primary of Lee-  Yang model  Figure 6: Periodic plane partition cor-  responding to level 5 excited state in vac-  uum representation of Lee-Yang model  It is also the simplest non-trivial minimal model,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' having the smallest number of states in  the vacuum representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Unlike the more famous Ising model it is non-unitary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Via the  correspondence between 4d N = 2 superconformal field theories and 2d vertex operator  algebras [55] it corresponds to the first model in the Argyres-Douglas series, labeled by  a pair of Dynkin diagrams (A1, A2) [56, 57] and is associated to a plane algebraic curve  p2 + x3 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  This minimal model has two primaries, one with ∆ = 0 and one with ∆ = − 1  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Recall  that if we specialize parameters of W∞ by imposing a condition of the form λ3 = N,  corresponding to truncation to Y00N algebra in the notation of [48, 52], the plane partitions  – 45 –  corresponding to states in the lowest weight representations are truncated in the direction  associated to λ3 so that there are at most N layers of boxes [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand,  if we impose two such conditions in two directions (as we should do in (AN1−1, AN2−1)  Argyres-Douglas minimal model), the irreducible representations have more states than if  we naïvely imposed both truncation conditions at the same time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Actually, what happens  in situations like this is that we effectively develop a periodic direction in the space of plane  partitions, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the plane partitions should be drawn on a cylinder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The periodic plane  partition corresponding to Lee-Yang ∆ = 0 lowest weight state is illustrated in Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Counting of states in ∆ = 0 irreducible representation is equivalent to counting of periodic  configurations of boxes that can be stacked on top of such ground state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can notice  several features of this box counting problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First of all, starting from the corner, we can  stack horizontally at most three boxes along the brown wall.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The fourth box in this direction  would not be supported from below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This corresponds to W3 algebra truncation with null  state at level four (corresponding to absent spin 4 generator).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Analogously, starting from  an empty configuration, we can only put two boxes on top of each other vertically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  third box would not be supported by anything from behind so it does not satisfy the plane  partition rule.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  This corresponds to Virasoro truncation of W∞ (and absence of spin 3  generator of the algebra).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But imposing simultaneously two conditions of this type leads  to periodicity and in turn to a relaxation of these rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We see that it we consider an L-  shaped configuration of 4 boxes with three boxes stacked horizontally and 2 vertically, this  configuration admits addition of fourth box in the horizontal direction (or which is the same  by periodicity, third box in the vertical direction).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Therefore, there is an additional state  at level 5 that would not be allowed if we would naïvely impose both truncation conditions,  which would effectively restrict the growth of the plane partitions to 2 × 3 rectangle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  configuration of boxes corresponding to this level 5 state in the vacuum representation of  Lee-Yang is illustrated in Figure 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The fact that the characters of irreducible representations count exactly such periodic  plane partitions applies to all WN minimal models and all their allowed primaries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  choice of a specific minimal model controls the periodicity of the corresponding plane par-  titions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, the choice of a primary is related to the choice of non-trivial  asymptotics along non-periodic directions (there are generically two such directions for WN  minimal models but only one such direction in the special case of Argyres-Douglas minimal  models).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In Figure 5 we show the configuration corresponding to the primary field ∆ = − 1  5  of the Lee-Yang model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It can be obtained from the configuration of figure 3 by adding an  infinite column of boxes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The periodicity conditions are not affected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Figure 4 on the other  hand illustrates the periodic configuration corresponding to the vacuum representation of  Virasoro c = 1  2 model, the Ising model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We see that the periodic stairs are offset relative  to Lee-Yang model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The fact that this model is a Virasoro minimal model can be seen  from the fact that the stairs have height 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, Ising model as all first  unitary minimal models of WN series is also a representation of Y012 truncation of W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Such truncations are characterized by having a null vector at level 6 in the vacuum repre-  sentation and we can clearly see this null vector by presence of a pit at coordinates (2, 3)  in the horizontal plane [52, 58].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 46 –  The characters of irreducible representations have particularly simple form in the case of  minimal models of Argyres-Douglas type (AN1−1, AN2−1) corresponding to minimal models  of simultaneously WN1 and WN2 algebras [27, 59] (we always assume that gcd(N1, N2) = 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In this case, a non-trivial asymptotic is possible only in one of the directions and the allowed  primaries are thus labeled by Young diagrams that fit in asymptotic N1 × N2 rectangle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Since there are  �N1 + N2  N1  �  =  �N1 + N2  N2  �  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  such Young diagrams, we would expect the same number of primaries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But not all of these  give inequivalent representations of W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Whenever there is a full row or column (of length  N1 or N2), we can remove it by a shift of the spectral parameter (which affects only the  zero mode of the Heisenberg algebra).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are N1 + N2 such identifications of primaries  so in total there are  (N1 + N2 − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  N1!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='N2!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  inequivalent primaries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The irreducible characters of the corresponding W∞ representation  can be read off from the asymptotic Young diagram λ as follows: the character is given by  a hook length formula  q∆− c  24 (q;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q)∞  (qN1+N2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' qN1+N2)∞  �  □∈λ  1  (qhook(□);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' qN1+N2)∞  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  where ∆ is the conformal dimension of the primary which can be combinatorially determined  as explained for example in [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Furthermore  (a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q)∞ =  ∞  �  j=0  (1 − aqj)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  is the q-Pochhammer symbol and hook(□) is the (periodic) hook length corresponding to  the box □ as illustrated in the following diagram for (A1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A2) minimal model:  1 3 4  4 1 2  4 1 3  2 4 1  3 4 1  1 2 4  1 2 4  3 4 1  4 1 2  1 3 4  2 3 4  1 2 3  4 2 3  3 1 2  3 4 2  2 3 1  2 3 4  1 2 3  1 2 3  2 3 4  ≃  ≃  ≃  ≃  ≃  ≃  ≃  ≃  ∆ = − 1  5 :  ∆ = 0 :  The yellow boxes form the corresponding asymptotic Young diagram λ and they are sepa-  rated from white boxes by the red line which is the projection of the asymptotic staircase.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Given a box, its hook length is given by the number of boxes to the left (the arm length)  plus the number of boxes above (the leg length) plus one (for the box itself).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We count the  boxes until we reach the red line, if needed periodically extending from the left to the right  and from the top to the bottom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We see that all the Young diagrams related by N1 + N2  – 47 –  identifications have the same collection of hook lengths.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the case of (A1, A2) minimal  model we see that  χ∆=0 =  q11/60  (q2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q5)∞(q3;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q5)∞  ≃ q11/60(1 + q2 + q3 + q4 + q5 + 2q6 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=')  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  χ∆=− 1  5 =  q−1/60  (q;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q5)∞(q4;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q5)∞  ≃ q−1/60(1 + q + q2 + q3 + 2q4 + 2q5 + 3q6 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  These functions count the states in the corresponding irreducible W∞ representations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To  get the counting of states in W1+∞, we should multiply these by the Heisenberg contribution  (q;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q)−1  ∞ obtaining expansions  1  �∞  n=1(1 − qn)χ∆=0 ∼ 1 + q + 3q2 + 5q3 + 9q4 + 14q5 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  1  �∞  n=1(1 − qn)χ∆=− 1  5 ∼ 1 + 2q + 4q2 + 7q3 + 13q4 + 21q5 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  which will be useful in the following.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As another example, for W3 ∩ W4 minimal model  (corresponding to (A2, A3) Argyres-Douglas with c∞ = − 114  7 ) the primary ∆ = − 4  7 with  asymptotic  has hook lengths  2 3 5 6  1 2 4 5  5 6 1 2  corresponding to W∞ character  q3/28  (q;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q7)∞(q2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q7)2∞(q5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q7)2∞(q6;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q7)∞  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Solutions of Bethe ansatz equations for ∆ = − 1  5  Now that we know enough information about the representations and their characters, we  can have a look at the corresponding solutions of Bethe ansatz equations (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First of  all we make a choice of the parameters of the algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Let us choose  ϵ1 = 2,  ϵ2 = 3,  ϵ3 = −5  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  with ψ0 = 1  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The corresponding λ-parameters are  λ1 = 3,  λ2 = 2,  λ3 = −6  5  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  and the W∞ central charge is  c∞ = (λ1 − 1)(λ2 − 1)(λ3 − 1) = −22  5  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  which is exactly the central charge of the non-unitary Lee-Yang model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As for the function  parametrizing the lowest weights, we choose  A(u) −→ (u − 5)(u − 6)  (u − 2)(u − 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  – 48 –  As discussed in [52], this can be done from the point of view of second asymptotic direction,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Virasoro algebra (N ↔ λ2) where we would write  (u − 2 − ϵ2)(u − 3 − ϵ2)  (u − 2)(u − 3)  = (u − 5)(u − 6)  (u − 2)(u − 3)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  or from the point of view of first direction, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' W3 algebra (N ↔ λ1) where the factorization  is instead  (u − 2 − ϵ1)(u − 3 − ϵ1)(u − 4 − ϵ1)  (u − 2)(u − 3)(u − 4)  = (u − 5)(u − 6)  (u − 2)(u − 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  The requirement of factorizability both as (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14) and (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15) (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' corresponding to both  truncations) determines all allowed primaries [52].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In our case there are only two of them  up to constant shifts of u-parameter (which does not change the W∞ representation but  changes the lowest weight with respect to Heisenberg algebra).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 1  At level 1, there is a single Bethe ansatz equation  q(x1 − 5)(x1 − 6)  (x1 − 2)(x1 − 3) = 1  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  with two solutions  5 − 11q +  �  1 + 34q + q2  2(1 − q)  ≃ 3 + 6q − 66q2 + 1158q3 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  and  5 − 11q −  �  1 + 34q + q2  2(1 − q)  ≃ 2 − 12q + 60q2 − 1164q3 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  We see that in the Yangian limit q → 0 the solutions are analytic and the Bethe roots  approach the weighted coordinates of positions where we can put the boxes: choosing the  corner of the vacuum periodic plane partition to be at coordinates (0, 0, 0), in the ∆ = − 1  5  we can put the first box either at coordinates (1, 0, 0) or (0, 1, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The weighted coordinates  of these are ϵ1 = 2 and ϵ2 = 3 which are exactly the limiting values of the Bethe roots  as q → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We could similarly study the behaviour as q → ∞ where we would find the  conjugate Yangian prediction for these limiting values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the local limit q → 1, we have  5 − 11q +  �  1 + 34q + q2  2(1 − q)  ≃ 4 − 1  3(1 − q) − 1  6(1 − q)2 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  and  5 − 11q −  �  1 + 34q + q2  2(1 − q)  ≃ −  6  1 − q + 7 + 1  3(1 − q) + 1  6(1 − q)2 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  We see that the first of these is regular as q → 1 and so it corresponds to W∞ excitation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  On the other hand, the second solution has a simple pole as q → 1 with residue given by  −ψ0ϵ1ϵ2ϵ3 so it corresponds to a Heisenberg excitation in line with the general discussion  in section 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 49 –  Finally, we have in addition two branch points in the q-plane at points  q = −17 ± 12  √  2  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  (note that these are inverse of one another as required by charge conjugation).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These two  points both lie on the negative real axis and as we continue the solutions of Bethe equations  around them, the solutions get exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This shows that the two sheets corresponding  to two different states at level 1 actually connect as we analytically continue in q-parameter  space, so there is a single connected Riemann surface covering the q-plane which captures  both Bethe roots at this level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We also see that the excitation purely in Heisenberg sub-  algebra can be transformed to purely W∞ excitation by analytic continuation in the twist  parameter q (and vice versa), so for generic values of q we cannot expect decoupling of these  degrees of freedom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Note also that for q equal to one of these two branch points the corresponding eigen-  states of ILW Hamiltonians have identical spectrum of all the conserved charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the  case of level 1 states discussed now the fact that by tuning one complex parameter q we  can make two Bethe roots agree is not so surprising, but as we will see such phenomenon  persists also at higher excited levels although generically we would expect these to be of  a higher codimension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But of course our system of algebraic equations is far from being a  generic one, so many special coincidencies are happening.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 2  At next level, each solution of BAE is given by a pair of Bethe roots (x1, x2)  solving a system of equations  1 = q(x1 − 5)(x1 − 6)  (x1 − 2)(x1 − 3)  (x1 − x2 + ϵ1)(x1 − x2 + ϵ2)(x1 − x2 + ϵ3)  (x1 − x2 − ϵ1)(x1 − x2 − ϵ2)(x1 − x2 − ϵ3)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  1 = q(x2 − 5)(x2 − 6)  (x2 − 2)(x2 − 3)  (x2 − x1 + ϵ1)(x2 − x1 + ϵ2)(x2 − x1 + ϵ3)  (x2 − x1 − ϵ1)(x2 − x1 − ϵ2)(x2 − x1 − ϵ3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  We see that we have a system of two equations of fifth degree for two unknowns which is  much more complicated than a single quadratic equation that we were solving previously.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  There are various possible approaches to solve these equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The most naïve one is to use Newton’s method to find numerically an approximate  solution starting from a random initial seed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this way we find generically 16 solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Since the equations themselves are invariant under the exchange x1 ↔ x2, the solutions  will also form either pairs of solutions related by this exchange or solutions with x1 = x2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  From the numerics we find three groups of solutions that do not mix among each other as  we analytically continue in q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first group are three solutions  (2, 5),  (3, 5)  (3, 6)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  which are q-independent (and can be associated to null states).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Next there are two degen-  erate solutions with x1 = x2 which are given by  x1 = x2 = 5 + 11q ±  �  1 − 34q + q2  2(1 + q)  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  – 50 –  Finally we have four solutions which are q-dependent and which have x1 ̸= x2 for generic q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  There is probably no explicit formula for these eight Bethe roots, but it is precisely these  that correspond to four states in the irreducible representation at level 2 and this is why  in the following we will mainly focus on these.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The Bethe roots corresponding to states in  irreducible representations of W1+∞ will be called physical in the following.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We can also try to learn something about the solutions analytically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can eliminate  one of the variables using the resultant of the two Bethe equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The resultant of BAE  with respect to x2 is a polynomial of degree 16 in x1 (with coefficients still depending on  q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This polynomial has linear factors corresponding to the integer roots x1 ∈ (2, 3, 5, 6)  with multiplicity 1 or 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Next we have a quadratic factor  (1 + q)x2  1 − (5 + 11q)x1 + 6 + 30q  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  whose solutions are the degenerate roots (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Finally,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' there is an irreducible degree 8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='polynomial  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(q − 1)5(q + 1)2x8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 − (q − 1)4(q + 1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='53q2 + 18q − 11  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ (q − 1)3 �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1207q4 + 828q3 − 446q2 − 180q + 31  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− (q − 1)2 �  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15443q5 + 571q4 − 8062q3 + 226q2 + 395q + 67  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 4(q − 1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30388q6 − 18560q5 − 10357q4 + 4678q3 + 53q2 + 400q − 122  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='150836q7 − 190341q6 + 25286q5 + 24859q4 − 4261q3 + 2758q2 − 1509q + 148  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 48  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='38460q7 − 35489q6 + 3469q5 + 1592q4 − 674q3 + 479q2 − 41q − 20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 144  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22125q7 − 13310q6 + 583q5 + 1020q4 − 756q3 + 119q2 + 66q − 19  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='x1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 1728  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1375q7 − 425q6 − 55q5 + 132q4 − 60q3 + q2 + 5q − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  whose roots are the 4 pairs of non-degenerate q-dependent Bethe roots that we identify  with the physical states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Solving this degree 8 equation for x1 determines x1 as a function  of q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Finally by calculating the greatest common divisor with respect to x2 of Bethe ansatz  equations reduces them to a linear equation for x2 which allows us to uniquely determine  x2 in terms of x1 and q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The formula is  x2 =  N  D1D2  N = (q − 1)3(q + 1)2x7  1 − (q − 1)2(q + 1)  �  25q2 + 6q − 7  �  x6  1  + 3(q − 1)  �  43q4 + 36q3 − 2q2 − 12q − 5  �  x5  1  +  �  1993q5 − 2059q4 − 2186q3 + 1958q2 + 373q − 295  �  x4  1  − 2  �  15839q5 − 10325q4 − 10612q3 + 5956q2 + 1037q − 599  �  x3  1  + 12  �  15315q5 − 7279q4 − 6216q3 + 2648q2 + 333q − 193  �  x2  1  − 72  �  6975q5 − 2405q4 − 1536q3 + 560q2 + 37q − 31  �  x1  + 864(5q + 1)  �  125q4 − 55q3 − 2q2 + 5q − 1  �  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  D1 = (q − 1)x2  1 + (5 − 11q)x1 + 6(5q − 1)  D2 =  �  1 − q2�2 x4  1 +  �  1 − q2� �  25q2 − 7  �  x3  1 + 4  �  58q4 − 41q2 + 4  �  x2  1  – 51 –  − 12  �  79q4 − 24q2 + 1  �  x1 + 144q2 �  10q2 − 1  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We see that it is a complicated yet very explicit map which we can use to find the second  Bethe root once we know the first one (for example from the resultant), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' we can use this  map to pair solutions of (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27) to form solutions of BAE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' By construction the corresponding  transformation of Bethe roots is involutive as it must be since the Bethe roots appear in  pairs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the Yangian limit q → 0, the zeros of (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27) can found using ordinary power series:  the eight solutions are  �  −3 − 18  7 q − 55458  1715 q2 + 6113358  420175 q3 + O(q4)  +2 − 144  5 q2 + 1692  175 q3 + O(q4)  �  −2 − 3q + 249  20 q2 − 4839  200 q3 + O(q4)  +3 + 84  5 q2 − 459  50 q3 + O(q4)  �  +2 + 3q + 555  4 q2 + 22623  8  q3 + O(q4)  +3 − 24q + 24q2 − 15789  2  q3 + O(q4)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  �  +2 − 12q2 + 2160  7 q3 + O(q4)  +4 + 60  7 q − 55176  343 q2 + 79819980  16807 q3 + O(q4)  The eight roots of the resultant were paired into 4 solutions of Bethe ansatz equations using  equation (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28) which gives us the second Bethe root once we know the first one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can  identify the Yangian q → 0 limit of these solutions with configurations of boxes in periodic  plane partitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The positions in which we can put two boxes and the corresponding  Yangian Bethe roots are  (ϵ1, 2ϵ1) = (2, 4)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  (ϵ1, ϵ1 + ϵ3) = (2, −3)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  (ϵ2, ϵ2 + ϵ3) = (3, −2)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  (ϵ1, ϵ2) = (2, 3)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  which are exactly the q → 0 limits of the perturbative solutions that we found.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A similar  analysis would apply to q → ∞ where we would find a very similar picture corresponding  to a conjugate representation (which in this case is the same one) up to a spectral shift.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We can also use the analytic techniques to find points in q-plane around which the so-  lutions have non-trivial monodromy, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' points in q-plane such that analytically continuing  around them allows us to go from one solution of Bethe ansatz equations to another.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First  of all, the solutions of the three groups of solutions cannot mix by monodromy because this  would not be compatible with analytic continuation in q (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' analytic continuation around  a point in q-plane of a solution with non-trivial q-dependence cannot produce q-independent  solution and analytic continuation of solution satisfying x1 = x2 will never result in solution  that does not satisfy this constraint).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The most interesting solutions which are those that  solve (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' the physical solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The discriminant of this equation is q-dependent  – 52 –  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='65  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='65  4  2  2  4  5  4  3  2  1  1  Figure 7: An illustration of non-trivial homotopy of solutions of Bethe ansatz equations  around q = q∗ ∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='168469 + 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='432772i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The left figure shows the curve in the q-plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  red dots are zeros of the discriminant so around these points the monodromy is potentially  non-trivial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The curve on the left encloses only one such singular point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The figure on the  right shows how four pairs of Bethe roots evolve in the complex plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We start at q = 0  with Yangian solutions blue → (2, 4), red → (−2, 3), yellow → (2, −3) and green → (2, 3)  and go around q = q∗ and return back to q = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We see that while the yellow and green  Bethe roots go back to their original values, the red and green Bethe roots are instead  pairwise exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  polynomial which tells us where in q-plane there can be a non-trivial monodromy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  discriminant factorizes such that the factors are of the following form:  D ∼ F 30  1 F 10  2 F 4  3 F4F 2  5 F 2  6  F1 = q  F2 = q − 1  F3 = q + 1  F4 = 25q4 − 1180q3 − 282q2 − 1180q + 25  F5 = q8 + 59q7 + 55q6 − 119q5 + 494q4 − 119q3  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  + 55q2 + 59q + 1  F6 = 49q12 + 2753q11 + 6044q10 + 250824q9 + 67633q8  + 669175q7 + 1739524q6 + 669175q5 + 67633q4  + 250824q3 + 6044q2 + 2753q + 49  All these factors are palindromic polynomials, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' q is a root of these if and only if q−1 is  a root which is compatible with the charge conjugation symmetry of the algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since ϵj  parameters as well as the parameters characterizing charges of the lowest weight vector are  real, the roots of these polynomials also appear in complex conjugate pairs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 53 –  We can use the homotopy method to study the monodromy of the solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since at  the Yangian points q → 0 or q → ∞ we can solve the Bethe ansatz equations exactly, we  can start from there, slowly deforming the homotopy parameter q in the complex plane and  at every step using Newton’s method to update the solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the Newton’s method  converges very rapidly away from special points in the q-plane, this is a very convenient way  to solve BAE at any given value of q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Starting with four physical solutions around q = 0, we  can study what happens as we go around zeros of the discriminant (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It turns out that  q = 0 (zero of F1) is a regular point where our solutions have no monodromy and actually we  can find a power series solutions around this point (converging up to nearest singular point  in q-plane).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The local point q = 1 has monodromy associated to it, but this monodromy  is such that only two Bethe roots of a given solution of BAE get exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The solutions  of BAE corresponding to different physical states do not get mixed as we go around q = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Also, as discussed in detail in the previous section, some solutions of BAE blow up as we  approach q = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These Bethe roots correspond to excitations of the Heisenberg subalgebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We have a similar situation around q = −1, but at this level there is no monodromy (since  there can be only one excitation of the twist 2 Heisenberg subalgebra).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For values of q  that are roots of F4 the monodromy is similarly only exchanging two Bethe roots in a  given solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There is no monodromy at all associated to roots of F5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Finally, the most  interesting case are the roots of F6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Around all these points the solutions of Bethe ansatz  equations are exchanged in a transitive manner, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' starting with any solution around q = 0,  by a suitable path around roots of F6 we can get any other of the four physical solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  This is somewhat analogous to the situation in other integrable models [54] where various  eigenstates of the set of commuting operators are connected as we analytically continue  in the parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One example of such monodromy around q ∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='168469 + 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='432772i is  shown in Figure 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' To summarize, the monodromy of solutions of (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27) as we vary q must  preserve the pairs of Bethe roots in a given solution, so the monodromy group is reduced  from the generic S8 to S4  2 ⋊ S4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Finally we want to study the solutions around q = ±1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  At local point q = 1, we  expect to find two solutions whose both Bethe roots blow up (corresponding to  and  excitations of Heisenberg algebra), one solution where only one Bethe root blows up while  the other one corresponds to level 1 state of W∞ and finally one finite solution corresponding  to level 2 state in W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is exactly the case as we can see from the solutions  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content='2 + O((1 − q)1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1−q − i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5(1 − q)− 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ i  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−12 + 27  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5(1 − q)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 + O((1 − q)1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1−q + 7 − 4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3(1 − q) − 2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3(1 − q)2 + O((1 − q)3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3(1 − q) − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6(1 − q)2 + O((1 − q)3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='– 54 –  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52 − 3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4(1 − q) − 3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='64(8 −  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)(1 − q)2 + O((1 − q)3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52 − 3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4(1 − q) − 3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='64(8 +  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='√  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)(1 − q)2 + O((1 − q)3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  As we go around q = 1, the only monodromy that is there is exchanging the Bethe roots in  a given solution of Bethe ansatz equations, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' symmetric polynomials of Bethe roots do  not undergo any monodromy and we expect this to be the general behaviour.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  By using the homotopy to continue four solutions corresponding to four level 2 states  from q = 0 to q = −1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' we see that three of the solutions have usual Taylor series expansion  around q = −1 and one solution that blows up as q → −1 (corresponding to twisted  Heisenberg algebra eigenstate),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  4 +  �  3 −  √  5 + 1  24  �  9  √  5 − 53  �  (q + 1) + O((1 + q)2)  4 −  �  3 +  √  5 + 1  24  �  −9  √  5 − 53  �  (q + 1) + O((1 + q)2)  �  4 −  �  3 −  √  5 + 1  24  �  9  √  5 − 53  �  (q + 1) + O((1 + q)2)  4 +  �  3 +  √  5 + 1  24  �  −9  √  5 − 53  �  (q + 1) + O((1 + q)2)  �  4 −  √  7  2 + 9  8(q + 1) + O((1 + q)2)  4 +  √  7  2 + 9  8(q + 1) + O((1 + q)2)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  �  �  �  −  6  1+q + 7 −  √  19  2  − 11  24(1 + q) −  �  11  48 +  5  16  √  19  �  (1 + q)2 + O((1 + q)3)  −  6  1+q + 7 +  √  19  2  − 11  24(1 + q) −  �  11  48 −  5  16  √  19  �  (1 + q)2 + O((1 + q)3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We see that the twisted level 2 Heisenberg excitation has the same singular behaviour (with  the same residue) as q → −1 as the usual Heisenberg excitations have for q → 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Although  it corresponds to a lowest excitation of the twisted Heisenberg algebra of even modes, at  the level of Bethe ansatz equations it is represented by a pair of singular Bethe roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Solutions of Bethe ansatz equations for ∆ = 0  Let us solve the Bethe ansatz equations also for the other primary, the translation-invariant  vacuum state ∆ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this case, the generating function of Yangian charges of the lowest  weight state is simply  u + ψ0ϵ1ϵ2ϵ3  u  = u − 6  u  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  so Bethe ansatz equations are of one lower degree which makes the analysis simpler.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 1  The Bethe equation is simply  1 = qx1 − 6  x1  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='38)  so we have only one solution with Bethe root  x1 = − 6q  1 − q  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='39)  whose only singularity is at the local point q = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  It corresponds to first Heisenberg  excitation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 55 –  Level 2  At level 2 Bethe equations are  1 = q x1 − 6  x1  (x1 − x2 + ϵ1)(x1 − x2 + ϵ2)(x1 − x2 + ϵ3)  (x1 − x2 − ϵ1)(x1 − x2 − ϵ2)(x1 − x2 − ϵ3)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='40)  1 = q x2 − 6  x2  (x2 − x1 + ϵ1)(x2 − x1 + ϵ2)(x2 − x1 + ϵ3)  (x2 − x1 − ϵ1)(x2 − x1 − ϵ2)(x2 − x1 − ϵ3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='41)  Numerical solution indicates that there are three pairs of non-trivial q-dependent solutions  corresponding to three physical states at level 2 in the vacuum representation and one  degenerate solution with x1 = x2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The factor of resultant corresponding to physical states  is degree 6 polynomial  (q − 1)4(q + 1)2x6  1 − 12(q − 1)3(q + 1)(3q + 1)qx5  1  +(q−1)2 �  521q4 + 360q3 + 2q2 − 19  �  x4  1−6(q−1)  �  649q5 + 43q4 − 40q3 − 48q2 − 33q + 5  �  x3  1  + 36  �  441q4 − 246q3 + 29q2 − 76q − 4  �  q2x2  1 − 216  �  155q2 − 34q + 23  �  q4x1 + 28512q6  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='42)  whose 6 roots correspond to three pairs of Bethe roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The identification between the pairs  is obtained as before by taking the greatest common divisor of Bethe equations and we find  a fractional linear map  x2 =  6q2(x1 − 6)  (q2 − 1)x1 − 6q2  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='43)  which can be checked to be involutive on the set of solutions of (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='42).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The discriminant of  the relevant factor of the resultant (corresponding to Bethe roots that are not identically  equal) is  D ∼ q12(1 − q)18(1 + q)4(5 − 66q + 5q2)×  × (196 + 8923q + 12800q2 + 59842q3 + 12800q4 + 8923q5 + 196q6)2  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44)  and the points in the q-plane where there are non-trivial monodromies are different than  the ones of ∆ = − 1  5 representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 3  The vacuum representation ∆ = 0 is slightly simpler than the primary ∆ = − 1  5  due to the fact that the generating function of Yangian lowest weight charges  A(u) = u − 6  u  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45)  has only single zero and a single pole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The number of zeros and poles of this function is  the quantity that (along with the level M) has the main influence on the degrees of Bethe  ansatz equations and the associated difficulty of solving it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The vacuum representation of  W1+∞ would have six states at level 3, but since we have a singular vector at level 3 (due  to Virasoro condition λ2 = 2), we will only have five states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The naïve numerical solution of the system of level 3 Bethe ansatz equations fails due  to the fact that at this level there appear continuous families of solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In fact, consider  – 56 –  a solutions of the form  �  �  �  �  �  �  �  x1  =  f(q)  x2  =  f(q) + ϵ1 = f(q) + 2  x3  =  f(q) + ϵ1 + ϵ2 = f(q) + 5  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='46)  �  �  �  �  �  �  �  x1  =  f(q)  x2  =  f(q) + ϵ2 = f(q) + 3  x3  =  f(q) + ϵ1 + ϵ2 = f(q) + 5  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47)  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' triples of Bethe roots satisfying a non-trivial resonance condition (related to the wheel  condition in shuffle algebra [60]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is clear that these are solutions of Bethe ansatz equa-  tions for any function f(q) if we write these equations in the polynomial form, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' if we  move all the numerators on one side and denominators on the other side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since there is a  one-parametric family of such solutions for any value of q, if we apply Newton’s method  with random initial seed, we will almost surely end up with a solution of this kind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  There is no problem with the homotopy method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The solutions of BAE at q = 0 are  either solutions of the family of solutions written above, or one of the following families of  discrete solutions:  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' solutions corresponding to physical states in the irreducible representation  (−10, −5, 0),  (−5, 0, 2),  (−5, 0, 3),  (0, 2, 3),  (0, 2, 4)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48)  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' null state solution (remnant of missing 6th state in the vacuum representation)  (0, 3, 6)  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' solutions  (−3, 0, 2),  (−2, 0, 3),  (−5, −3, 0),  (−5, −2, 0),  (0, 2, 5),  (0, 3, 5)  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' solutions with degenerate Bethe roots  (−5, −5, 0),  (−5, 0, 0),  (0, 0, 2),  (0, 0, 3),  (0, 2, 2),  (0, 3, 3)  We can project the set of Bethe solutions corresponding to level 3 states in the vacuum  module (case 1 at q = 0) to complex line (eliminating variables x2 and x3 from Bethe  equations) using resultants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As a first step in the reduction, we evaluate the resultant for  the first and second Bethe equation with respect to variable x3 and the largest irreducible  factor is a polynomial in x2 of degree 15 (with coefficients which are polynomials in x1 and  q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Similarly, by taking the resultant of first and third Bethe equation in variable x3 and  extracting the largest irreducible factor, we get another polynomial of degree 15 in x2 with  coefficients which are polynomials in x1 and q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that if we did the same procedure  with second and third Bethe equations, we would get a polynomial in x2 of degree 24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 57 –  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  Figure 8: Zeros of the discriminant of the polynomial whose zeros are exactly the 15 Bethe  roots of the Lee-Yang vacuum representation at level 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Only around these points in the  q-plane the Bethe roots can have non-trivial monodromy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The zeros are symmetric under  complex conjugation q → ¯q as well as under spherical inversion q → q−1 so we do not show  most of the zeros outside of the unit disc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that apart from the special points q = 1  and q = −1 which lie on the unit circle, there are also other special points with modulus  |q| = 1, in particular the cubic roots of unity q = e±2πi/3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Now we calculate the resultant with respect to x2 of the two degree 15 polynomials in x2  that we found before.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The resulting polynomial is a polynomial of large degree in x1 with  coefficients that are polynomials in q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The largest irreducible factor is of degree 120 in x1,  but this is not the factor we are interested in (we can for example check that the solutions  obtained by homotopy from the physical solutions (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48) are not zeros of this factor).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  factor that we are interested in is the irreducible factor of degree 15 in x1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Its explicit form  is rather complicated and is given in appendix F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For a given q its roots are exactly the  five triples of Bethe roots corresponding to five solutions of BAE associated to five physical  level 3 states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Having a single polynomial whose roots are in one-to-one correspondence  with the physical Bethe roots is very convenient starting point to study Puiseux series  expansions of the solutions around any value of q, for example using the Newton’s polygon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Having an irreducible polynomial with these properties is also useful in order to show that  the analytic continuation in q parameter does not mix these physical solutions of BAE with  other solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Discriminant of this polynomial tells us around which points in the q-plane  the solutions undergo a non-trivial monodromy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are in fact 91 such special points  and their positions in the q-plane are illustrated in Figure 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 58 –  The expansion of the solutions around q = 0 produces is a regular Taylor series ex-  pansion with rational coefficients as shown in appendix F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The expansion of physical  solutions around local point q = 1 is given in appendix F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first of these solutions  has limit (0, 3, 6) as q → 1 which coincides with the constant q-independent solution (0, 3, 6)  but for q ̸= 1 these are different solutions of BAE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' They lie on different branches (different  factors of the resultant) so they cannot mix as we move around q-plane (but this does not  prevent them from coinciding at special values of q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The second solution corresponds to  one Heisenberg root and level 2 excitation of W∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The third solution has three Heisenberg  roots which are cyclically exchanged as we go around q = 1 and corresponds to state  of Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The last two states have also three Heisenberg roots, but the mon-  odromy around q = 1 only exchanges two of their roots while the third root is single-valued.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  These correspond to  and  excitations of Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 3 - twisted local limit q → −1  The limit q → −1 is also a singular limit for some  Bethe roots, concretely for those which are associated to excitations of even mode subalgebra  of the Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The degree 15 factor of the resultant given in appendix F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  simplifies to  (x−3)3(28−78x+157x2−48x3+4x4)(17424−6864x+2332x2−612x3+141x4−18x5+x6)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='49)  which is of degree 13, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  we lost two roots (corresponding to Bethe roots that blew  up in the limit).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Using the homotopy method, we see that the roots of discriminant are  combined to solutions of BAE in the following manner: the six roots of the sextic factor give  two complex conjugate solutions of Bethe ansatz equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The four roots of the quartic  equation together with two roots x = 3 give other two complex conjugate solutions of BAE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The last physical solution of BAE in q → −1 limit has Laurent expansion  �  �  �  �  �  �  �  x1  = −  6  q+1 + 12+  √  19  2  − 59  24(q + 1) + O((q + 1)2)  x2  = −  6  q+1 + 12−  √  19  2  − 59  24(q + 1) + O((q + 1)2)  x3  = 3 − 3  2(q + 1) − 3  4(q + 1)2 + O((q + 1)3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50)  The Bethe roots x1 and x2 are singular and correspond to level 2 excitation of the Heisen-  berg algebra and the third root corresponds to the excitation of the algebra which is the  commutant of the twisted Heisenberg algebra in W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 3 - other twisted local limits q → e±2πi/3  There are other points in the q-plane  where one of the Bethe roots becomes singular.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The easiest way of seeing such points is  by looking at the leading coefficient x15 in the resultant characterizing all physical Bethe  roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Bethe roots blow up exactly when this leading coefficient vanishes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the example  studied here the number of Bethe roots that blow up is captured by this polynomial in q:  we have  β15 = (q − 1)10(q + 1)2(q2 + q + 1)3  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='51)  and we can see that indeed ten Bethe roots blow up as q → 1 and two Bethe roots blow up  as q → −1 as confirmed by explicit calculations above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We also see that three Bethe roots  – 59 –  should blow up when q → e±2πi/3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is exactly what is happening.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The corresponding  singular solution around q = e2πi/3 has Bethe roots of the form  − ψ0ϵ1ϵ2ϵ3e2πi/3  q − e2πi/3  + γ0 + O((q − e2πi/3)1)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52)  where γ0 are the three roots of the equation  γ3  0 − 18γ2  0 + 89γ0 − 102  √  3 + 10i = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='53)  Since the leading and subleading terms have no monodromy around q = e2πi/3 and distin-  guish the three roots, there is no monodromy at all orders, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' we have Laurent expansion  of the Bethe roots in (q − e2πi/3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Perturbative expansion at q = 0 and residue formula  Just as the constant coefficient in q → 0 expansion can be read off directly from the  combinatorics of periodic plane partitions, so can be the O(q) coefficient: it is simply given  by the residue of the generating function of the Yangian higher spin charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Consider  for concreteness level 3 descendants of ∆ = 0 primary in Lee-Yang model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have five  physical solutions as listed in (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Their corresponding generating functions of Yangian  higher spin charges are  (0, ϵ1, 2ϵ1) = (0, 2, 4) ⇝ ψ(u) = (u − 9)(u − 1)(u + 2)  (u − 4)(u − 3)(u + 5)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54)  (0, ϵ3, 2ϵ3) = (0, −5, −10) ⇝ ψ(u) = (u − 6)(u − 5)(u + 12)(u + 13)  (u − 3)(u − 2)(u + 10)(u + 15)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='55)  (0, ϵ1, ϵ2) = (0, 2, 3) ⇝ ψ(u) =  (u − 8)(u − 7)(u − 1)u(u + 1)  (u − 5)(u − 4)(u − 3)(u − 2)(u + 5)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='56)  (0, ϵ1, ϵ3) = (0, 2, −5) ⇝ ψ(u) =  (u − 7)(u − 6)u(u + 1)(u + 7)(u + 8)  (u − 4)(u − 3)(u − 2)(u + 3)(u + 5)(u + 10)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='57)  (0, ϵ2, ϵ3)(0, 3, −5) ⇝ ψ(u) =  (u − 8)(u − 1)u(u + 7)(u + 8)  (u − 3)(u − 2)(u + 2)(u + 5)(u + 10)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='58)  Combinatorially, they correspond to adding three boxes to ground state configuration of  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can put pile of three boxes along first or third directions or an L-shaped  configuration of boxes in any of the three planes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The O(q1) term in expansion of ILW Hamiltonians comes from the matrix element  between ⟨□| and |□⟩ states in the auxiliary space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As such, these matrix elements are related  to amplitude of addition and removal of a box in a Young diagram.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The product of these  two amplitudes (which is independent of the normalization of the vectors in representation  space) is known to be expressible in terms of a residue of the generating function of Yangian  charges ψ(u), see [27] section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For this reason, it is not surprising that we have the  following empirical formula for O(q1) term in the expansion of the Bethe roots around  q = 0:  x = x0 − q · resu→x0 ψ(u) + O(q2)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59)  – 60 –  where x0 is the q → 0 limit of the given Bethe root.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Applying this formula to functions  in (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54) exactly reproduces the first order terms in appendix F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since ψ(u) only has  poles at points where a box can be added or removed [27], the Bethe roots corresponding  to boxes deeper in the Young diagram start at higher orders in q-expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can see  from explicit calculations such as those given in F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 that the first non-trivial power of q  (apart from the constant term) is given by (one plus) the number of boxes that need to be  removed from the Young diagram before the given box becomes removable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All of this is  consistent with the analysis in appendix D of [61] where Bethe equations are studied to the  first order in q-expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Numerical tests in first unitary W4 model  In this section we want to numerically test the formulas (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44) and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we want spin  4 field U4(z) to be non-trivial, we need to have rank of WN algebra to be at least 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For  this reason and for concreteness we choose the first unitary minimal model of W4 algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The λ-parameters of W∞ are determined by the constraints  1  λ1  + 1  λ2  + 1  λ3  = 0,  2  λ1  + 1  λ2  + 0  λ3  = 1,  λ3 = 4  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='60)  (the middle equation corresponds to the choice of the first unitary minimal model).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These  equations have unique solution  λ1 = −2  3,  λ2 = 4  5,  λ3 = 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='61)  The corresponding central charge is  c∞ = (λ1 − 1)(λ2 − 1)(λ3 − 1) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='62)  In general, for the first unitary minimal model of WN algebra we would have  c∞ = 2(N − 1)  N + 2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='63)  Next we calculate the Nekrasov-like parameters, imposing the conventional restriction  ϵ1ϵ2 = −1 that fixes the overall scaling symmetry up to an overall sign.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We find  ϵ1 =  �  6  5,  ϵ2 = −  �  5  6,  ϵ3 =  �  5  6 −  �  6  5  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='64)  and  ψ0 = 4,  α0 =  �  5  6 −  �  6  5 = − 1  √  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='65)  Finally, we restrict to the vacuum representation so the generating function of higher spin  charges of the ground state is  A(u) = u + ψ0ϵ1ϵ2ϵ3  u  =  u +  4  √  30  u  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='66)  – 61 –  With this choice, all ψj, j ≥ 1 vanish.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Writing this in terms of Coulomb parameters aj,  A(u) =  N  �  ℓ=1  u + aℓ − ϵ3  u + aℓ  ,  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='67)  we can determine these to be  a1 = 0,  a2 =  1  √  30,  a3 =  2  √  30,  a4 =  3  √  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='68)  Finally, we want to know how many states there are in the vacuum representation of this  unitary minimal model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We could either use the general Weyl character formula [44], or  simply count boxes in staircase configuration as in Figure 4, but with the height of green-  brown wall being 4 instead of 2 (since we are considering W4 minimal model).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The position  of the pit in the horizontal yellow plane is still the same, because both models are first  unitary minimal models so have a null state at level 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Counting the boxes, we find the  character proportional to  1 + q + 3q2 + 6q3 + 13q4 + 23q5 + 45q6 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='69)  Probably the easiest way to get this is to consider first MacMahon function counting all  plane partitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At level 5 we have one less state because we are in W4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At level 6 there are  three missing states, one of them being prohibited by the existence of the pit and the other  two states correspond to plane partitions with 6 boxes whose height exceeds 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In order to  find number of states in W4 vacuum representation, we need to subtract the contribution  of Heisenberg algebra and we finally find the state counting function  1 + q2 + 2q3 + 4q4 + 6q5 + 12q6 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='70)  Let us now find the eigenvalues of W3,0 and S4 and match them with solutions of BAE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 0  Since formulas (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44) and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48) only give eigenvalues relative to the lowest weight  state, we first calculate the eigenvalue of W3,0 and S4 on the vacuum state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The first one  vanishes by parity the second one has eigenvalue  −  121  115200.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='71)  In the following, we will list the eigenvalues of S4 relative to this value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 1  The analysis at level 1 is very simple becase there are no states at this level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 2  On level 2 we expect only one physical solution that is regular as q → 1, since  we have only one state  L−2 |0⟩ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='72)  W3,0 acting on this state is zero by parity, while S4 eigenvalue relative to vacuum is  − 121  240 = −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5041¯6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='73)  – 62 –  The physical solution of Bethe equations is  x1 = −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='807679 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' ,  x2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='077382 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='74)  and formulas (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44) and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48) give us eigenvalues zero and −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5041¯6 in agreement with  the explicit calculation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 3  Here we expect two states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the basis L−3 |0⟩ and W3,−3 |0⟩ the matrix of W3,0  is  �  0 4  5  6 0  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='75)  The matrix is off-diagonal due to parity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The eigenvalues are  ±  �  24  5 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='76)  The matrix of S4 relative to the lowest weight state is  �  − 363  160  0  0  − 363  160  �  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='77)  with obvious eigenvalues.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' These matrices also clearly commute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The corresponding solu-  tions of BAE are  (−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='39495, −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='847418, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0514826),  (−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='781779, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='117121, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='664658)  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='78)  which using (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44) and (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48) give exactly the eigenvalues we want.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Note that due to the  fact that every iteration of Newton’s method doubles the number of digits, we can find the  Bethe roots with almost arbitrary precision once we have the right initial seed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Level 4  Let us finally look at solutions at level 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are 4 states, the parity even  states  L−4 |0⟩ ,  L2  −2 |0⟩ ,  W4,−4 |0⟩  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='79)  and one parity odd state  W3,−4 |0⟩ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='80)  The matrix of W3,0 must be block off-diagonal in this basis and it is equal to  �  �  �  �  �  0 0  0  64  45  0 0  0  256  135  0 0  0  −8  8 8 − 121  270  0  �  �  �  �  �  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='81)  with eigenvalues  + 2  �  113  15 , −2  �  113  15 , 0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='82)  – 63 –  The matrix of S4 is block diagonal  �  �  �  �  �  − 121  24  − 121  60  − 242  2025  0  − 121  90 − 1331  360  3388  6075  0  12  24  55  72  0  0  0  0  − 847  120  �  �  �  �  �  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='83)  with eigenvalues  − 847  120, −847  120, 11  120  �  −5 + 6  √  31  �  , 11  120  �  −5 − 6  √  31  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='84)  It is easy to check that the matrices representing W3,0 and S4 commute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The corresponding  solutions of BAE are  ξ1 = {−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='69167 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25460i, −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='861612, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0396581}  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='85)  ξ2 = {−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='769955, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='131316, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='961369 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='254598i}  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='86)  ξ3 = {−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='756691 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='092167i, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0263942 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0921672i}  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='87)  ξ4 = {−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='41680, −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='817274, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0869769, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='686498}  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='88)  and it is easy to check that these give the right values of W3,0 and S4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the vacuum  representation is self-conjugate, the transformation  xj(q) �→ ˜xj(q) = −xj(q−1) − ψ0ϵ1ϵ2ϵ3  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='89)  maps (physical) solutions of Bethe equations to solutions of Bethe equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since the  local point q = 1 is also invariant under q → q−1, given any solution of Bethe equations xj  at q = 1,  − xj − ψ0ϵ1ϵ2ϵ3  (7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='90)  is also a solution of Bethe equations at q = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the present situation this transformation  exchanges ξ1 ↔ ξ2 since they have opposite values of W3,0 charge and keeps ξ3 and ξ4  invariant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can use this symmetry to decrease the number of independent BAE and  Bethe roots to 2 and use this to analytically study the Bethe equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  8  Outlook  The results of this article are of technical nature, but they can be a starting point or  ingredients in pursuing various future directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Decoupling of W∞ and combinatorics of W∞ states  It is very well-known that  states in lowest weight representations of Heisenberg algebra can be enumerated by Young  diagrams.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The Yangian picture of W1+∞ allows us to enumerate states in lowest weight  representations of W1+∞ in terms of tuples of Young diagrams, in terms of plane parti-  tions (possibly with Young diagram asymptotics) or in terms of periodic plane partitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Which of these is realized depends on the choice of the parameters of the algebra (physical  model) and on the lowest weights (choice of the primary).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, without the  – 64 –  Heisenberg factor, there is no known natural way of enumerating the states of W∞ repre-  sentations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The ILW conserved quantities studied here however seem to offer one solution:  given any curve in the complex q-plane starting at q = 0 and ending at q = 1 and avoiding  points where the solutions become ambiguous, we can interpolate from eigenstates of Yan-  gian conserved quantities at q = 0 to pairs of eigenstates of Heisenberg × W∞ conserved  quantities at q = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A natural choice of such curve would be along the interval (0, 1), but  since we have seen that there are singular points on the positive real axis, one should go  either infinitesimally above or below the real axis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At any finite level M there can be no  accumulation points (because all the equations can be reduced to polynomial equations of  finite order) so such prescription is well-defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It would be interesting to understand such  a map in more detail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Behaviour of Bethe roots around special points  The points q = 0 and q = ∞ are  associated to Yangian conserved charges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In examples studied here all Bethe roots had nice  Taylor expansion around these points (and we found nice combinatorial interpretation of  the first two Taylor series coefficients).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It would be nice if there was a nice combinatorial  way of calculating higher order terms in the expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One of the reasons is that at higher  levels there are continuous families of unphysical solutions of BAE so one needs to go to  higher orders in Taylor expansion in order to fully specify the initial conditions in order to  use the monodromy method [53].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The local behaviour around the point q = 1 as well as around other roots of unity  is more puzzling.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The (twisted) Heisenberg subalgebras decouple at these points and the  Bethe roots associated to such subalgebras of W1+∞ blow up.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But the local behaviour of  Bethe roots encodes information about these Heisenberg excitations in very subtle way: the  higher conserved quantities of Heisenberg algebra appear at higher orders in Laurent series  expansion, but at these orders, the (twisted) Heisenberg Bethe roots interact non-linearly  with the remaining Bethe roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is rather surprising how simple discrete information  such as the Heisenberg Young diagram is captured by non-linear Bethe equations and how  it is encoded in the local behaviour of the Bethe roots around these roots of unity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Proof of FJMM formula, shuffle algebra  The main missing step in calculations in  this article is the fact that we did not attempt to prove the Feigin-Jimbo-Miwa-Mukhin  formula for the spectrum of Hq(u) (and neither did we prove the associated Bethe ansatz  equations).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' What we did was to numerically verify that the first five ILW Hamiltonians  calculated from the instanton R-matrix have spectrum as predicted by FJMM formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It  would be very useful to have algebraic derivation of Bethe ansatz equations along the lines  of algebraic Bethe ansatz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One problem is that in the usual spin chain one has access to  ladder operators that commute for any value of the spectral parameter, so it is easy to write  an off-shell Bethe state parametrized by a collection of spectral parameters, in which it is  symmetric (as a consequence of the commutativity).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The natural ladder operator e(u) that  we have in W1+∞ however does not commute with itself at different values of u.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This seems  to be an obstruction for following the standard algebraic Bethe ansatz procedure literally.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  On the other hand, the algebra of ladder operators in W1+∞ has beautiful shuffle algebra  description [60], where all the ladder operators are labeled by symmetric polynomials and  – 65 –  the associative product of the algebra gets translated to star product remotely reminiscent of  the Moyal product.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is actually this shuffle algebra picture that is an important ingredient  of the proof by Feigin-Jimbo-Miwa-Mukhin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Map between solutions of different Bethe ansatz equations  Currently we have at  our disposal two different looking sets of Bethe ansatz equations, the equations of Gaudin  type, introduced by Bazhanov, Lukyanov and Zamolodchikov (for Virasoro algebra) and  the equations of XXX spin chain type (but with higher order scattering amplitude) studied  by Litvinov.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The advantage of Litvinov’s equations is that they are uniform for the whole  W1+∞, respect the symmetries of the algebra and in addition come with natural monodromy  parameter that allows their solution using the homotopy method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, the  Gaudin type equations have been studied more thoroughly and there is clear connection  via ODE/IM correspondence to quantized spectral curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The KdV conserved charges are  encoded in WKB expansion of the wave function [62] which is therefore a natural generating  function of the higher conserved quantities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  It would be really useful to understand the map between the two pictures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' At every  finite level, we have finite number of Bethe roots and an infinite set of algebraic equations  connecting them, so one would hope that there should be a natural map relating these.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In W1+∞ there are two kinds of generating functions (local fields, currents) that one can  introduce to describe the algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the first point of view, we introduce the generating  function by summing over Fourier modes and the resulting generating function becomes a  local field in CFT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The parameter of the generating function is simply the coordinate on the  CFT worldsheet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A second approach is to sum over the spin label of the W1+∞ generators,  obtaining Yangian currents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The associated parameter of these generating functions is the  spectral parameter and lives in the same space where the zero modes of Heisenberg fields  (or Coulomb parameters) live.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The differential operators such as the Miura operator act  in the CFT space, but Litvinov’s Bethe ansatz equations are in the spectral parameter  space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand, the picture of Bazhanov, Lukyanov and Zamolodchikov involves  a Schrödinger differential operator with monster potential and the Bethe roots live in the  space where the differential operator acts, the Bethe roots being positions of singularities  of the potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It would seem natural to identify the Miura and BLZ operators, since for  WN algebra they are both N-th order ordinary differential operators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But as argued in [24],  we should not do so, in particular because for simple Lie algebras which are not Langlands  self-dual the two operators are related to Langlands dual algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If there was a natural  map between Bethe roots of Litvinov and BLZ Bethe equations, one could understand the  relation between the two spaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the related quantum toroidal setting such relation is  understood thanks to so-called Miki automorphism [63] which exchanges the mode and spin  spaces (which is geometrically related to fiber-base duality [64]) and the fact that there can  be different systems of Bethe ansatz equations associated to the same physical system is an  example of more general phenomenon called spectral duality [65–68].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There is also a close  connection to (affine) Gaudin models, starting from [24] and recently discussed for example  in [69–73].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 66 –  Gluings and BPS algebras  It is an important open question to describe the space  of vertex operator algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In [49, 52], a large class of vertex operator algebras was  constructed with W1+∞ or its truncations YN1N2N3 serving as fundamental building blocks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A parallel construction in the Yangian language was studied in [74–78].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  But there are  other important vertex algebras which seem to require more complicated basic elements  [45, 79].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One such generalization is to consider the Grassmannian vertex operator algebra  as a more general building block.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Just as W1+∞ is a two-parametric family of algebras,  the unitary Grassmannian coset algebras depend on three complex parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But there  are indications from the representation theory [79] that these algebras are part of four-  parametric family of algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Performing a OPE bootstrap for Grassmannian analogously  to [19, 20] is much more difficult due to significantly larger number of local fields, so it would  be good to find other approaches to study these algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Due to their simple structure,  Bethe ansatz equations seem to be a natural starting point for such generalizations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' See  [80] for recent discussion in the context of BPS algebras associated to quiver gauge theories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Hamiltonian structures and KP hierarchy  On the classical level, many integrable  systems admit bi-Hamiltonian structure, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' two Poisson brackets whose linear combina-  tions are also Poisson brackets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Kadomtsev-Petviashvili hierarchy is one of such integrable  systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' W1+∞ discussed here can be thought of as quantized KP hierarchy with respect  to so-called second Hamiltonian structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Interestinly, in [81], the authors quantized KP  equation directly with respect to the first Hamiltonian structure and by directly using the  coordinate Bethe ansatz obtained the same Bethe ansatz equations as those considered  here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It would be really interesting to understand how to relate the different Hamiltonian  structures at quantum level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Thermodynamics and modular properties of the higher local charges  There is  a very nice interplay between low energy and high energy properties of two-dimensional  conformal field theories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In particular, studying CFT on a torus for different values of  the modular parameter lead Cardy [82] to a formula which relates the counting of highly-  excited states to low energy properties of the system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On mathematics side, this manifests  by the fact that characters of irreducible representations of vertex operator algebras often  transform nicely under modular transformations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We can refine this IR/UV duality by introducing various probes in our system, the  simplest being an integral of local fields such as (TT)(z) along a spatial circle (for a nice  recent discussion see [83, 84]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Since (TT)(z) is quasi-primary, it transforms nicey under  conformal transformations (in fact it transforms under global conformal transformations of  Riemann sphere in the same way as primary fields), so naïvely we would expect nice modular  properties of torus partiton functions with insertions of higher spin charges such as (TT)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The problem is that in order to calculate the cylinder zero mode, we need to integrate  along the spatial cycle and this is in turn mapped to a temporal cycle under modular S-  transformation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A clever idea of Dijkgraaf [85] is to use the translation-invariance along  the time direction on the torus to average the expectation value of (TT)0, extending the  integral along the cycle to an integral over the whole torus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' After doing this, the integration  region is invariant under modular transformations so the characters refined by insertions  – 67 –  of operators such as (TT)0 still transform nicely under modular transformations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Once we  insert more such operators, the argument has to be refined, because the local operators can  have singularities at coincident points and a regularization is needed to resolve that, leading  to modular anomalies that are correlated to operator product expansions of the local fields  whose zero modes we are inserting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The higher spin extensions have not received so much attention (but see [86–88] for  recent discussion), so it would be very interesting to understand the interplay of modularity  with higher spin symmetries of W1+∞ more thoroughly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We saw many (quasi-)modular  forms appearing in expansions of various ILW quantities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The construction of conserved  quantities from R-matrix by algebraic Bethe ansatz introduces an auxiliary torus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If we keep  the quantum space to be on a cylinder, there is no reason to expect modular invariance to be  there.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the explicit calculations, we saw that the matrix elements of ILW Hamiltonians  were rational functions of q, all of the Eisenstein series could be eliminated by redefinition of  Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Also the Bethe equations have purely rational form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The situation changes  when we put the quantum space on a torus as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The configuration becomes symmetric  and the infinite sum of matrix elements of ILW Hamiltonians have similar form to Eisenstein  series and we can ask if there are any transformations acting on both tori that would be  symmetries of the setup.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' One would need to understand the interaction between combined  modular transformations acting in certain way on both tori and the insertion of R-matrix  coupling both tori.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The thermodynamic properties enter the game also if we want to understand the local  limit of ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The Yangian limit, q → 0, corresponds to low temperatures  in the auxiliary torus, where the lowest energy states dominante the trace.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this limit,  the Bethe roots of the quantum space are frozen to their Yangian positions, which can be  described using combinatorics of plane partitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' As we increase q, the excited states in the  auxiliary torus contribute as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the local limit q → 1 we are removing the regulator,  so the highly excited states should dominate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The typical Young diagram converges to a  limit shape and it is the geometry of this limit shape that should control the Hamiltonians  in the local limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Elliptic Calogero model  To simplify the calculations, we could try to choose a simpler  auxiliary space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In particular, there are representations of the algebra where the generators  of algebra act as quantum mechanical differential operators such in Calogero systems where  finite number of particles in one direction interact with 1/r3 forces when particles are close  to each other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The Miura operator can be thought of as a representation of universal  R-matrix with one of the spaces being the space of functions of z variable on which the  derivatives act [39, 89].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Applying the algebraic Bethe ansatz but with Calogero space being  the auxiliary space could lead to simpler expressions for ILW Hamiltonians.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The transition from Calogero systems to 2d conformal theory is the second quantization,  where the collective coordinates correspond to Fourier modes of CFT fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The total  momentum of the system (which is quantized with integer steps) becomes CFT L0 operator  (which has the same level spacing) and the usual Calogero Hamiltonian corresponds to  spin 3 conserved quantity in CFT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It would be nice if Litvinov’s Bethe ansatz equations  – 68 –  applied also to the finite dimensional system before the second quantization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Nekrasov and  Shatashvili [28] found equations that describe the spectrum of elliptic Calogero model, but  their equations take the form of thermodynamic limit of Litvinov’s equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Taking the  thermodynamic limit to go from a system of finite number of particles to a system with  infinite number of particles seems to be very natural, but it is less clear what is the rôle  of thermodynamic limit used to parametrize the solution of elliptic Calogero model which  has finite number of particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' There are also elliptic Bethe ansatz equations by Felder and  Varchenko [90] which could again be spectral dual of rational ILW equations studied here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  It would be very interesting to see how these results about elliptic Calogero model fit in  the picture discussed here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Acknowledgements  We would like to thank to Lorenz Eberhardt, Matěj Kudrna, Andrew Linshaw, Alexey  Litvinov, Alex Maloney, Go Noshita, Paolo Rossi, Paolo Rossi, Martin Schnabl, Alessandro  Sfondrini, Bogdan Stefański, Yuji Tachikawa, Alessandro Torrielli, Petr Vaško, Miroslav  Veľk and especially to Yutaka Matsuo for useful discussions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The research was supported  by the Grant Agency of the Czech Republic under the grant EXPRO 20-25775X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The  research was partially supported by Grant-in-Aid MEXT/JSPS KAKENHI 18K03610.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' AW  also wants to thank the FMSP program, JSPS Fellowship, and JSR Fellowship for their  financial support.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A  Fourier expansions and conformal normal ordering  Here we will compare the conformal normal ordering on the complex plane as well as on  the cylinder in terms of the corresponding Fourier modes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Complex plane  We will start with the case of complex plane which is usually discussed in the textbooks  [91].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' See also the summary in [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' A field A(z) (for simplicity of notation we consider  holomorphic fields) of conformal dimension h has Fourier expansion  A(pl)(z) =  �  m∈Z  z−m−hA(pl)  m .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  There are two basic operations that produce more complicated fields – the derivative and  the normal ordered product of fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Derivatives  In terms of their Fourier modes, the derivative ∂A has modes related to  those of A via  (∂A(pl))n = −(h + n)A(pl)  n  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  as can be easily seen by taking the derivative of Fourier expansion of A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 69 –  Normal ordering in terms of Fourier modes  The normal ordered product is slightly  more complicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' By definition, the (conformal) normal ordered product (AB) of (bosonic)  local fields A and B is defined by  (AB)(pl)(w) =  1  2πi  �  w  dz  z − wA(pl)(z)B(pl)(w)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  =  1  2πi  �  |z|>|w|  dz  z − wA(pl)(z)B(pl)(w) −  1  2πi  �  |z|<|w|  dz  z − wB(pl)(w)A(pl)(z)  where the fields are implicitly radially ordered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Using the identities  1  2πi  �  |z|>|w|  dz  z − wz−n =  �  0  n > 0  w−n  n ≤ 0  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  and  1  2πi  �  |z|<|w|  dz  z − wz−n =  �  −w−n  n > 0  0  n ≤ 0  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  we find the Fourier expansion of (AB) to be of the form  (AB)(pl)(w) =  �  k  w−hA−hB−k(AB)(pl)  k  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  with  (AB)(pl)  n  =  �  k≤−hA  A(pl)  k  B(pl)  n−k +  �  k>−hA  B(pl)  n−kA(pl)  k  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  which expresses the Fourier modes of the composite field (AB) in terms of those of A and  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' If A and B were anticommuting, there will be an additional minus sign every time the  order of A and B is exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Commutators of Fourier modes  It is useful to derive the relation between the commu-  tator of Fourier modes of two local fields A and B and their operator product expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Given two local fields A and B of dimensions hA and hB, their Fourier modes can be  extracted by contour integral  A(pl)  m  =  �  0  dz  2πiA(pl)(z)zm+hA−1  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  and similarly for B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can compute the commutation relations between the modes as  �  A(pl)  m , B(pl)  n  �  =  �  0  dw  2πi  �  |z|>|w|  dz  2πizm+hA−1wn+hB−1A(pl)(z)B(pl)(w)  −  �  0  dw  2πi  �  |z|<|w|  dz  2πizm+hA−1wn+hB−1B(pl)(w)A(pl)(z)  =  �  0  dw  2πi  �  w  dz  2πizm+hA−1wn+hB−1A(pl)(z)B(pl)(w)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  =  �  k>0  �m + hA − 1  k − 1  �  {AB}(pl)  −k,m+n  – 70 –  In the second equality we performed the standard contour deformation, deforming the  difference of two pairs of contours into a w-contour around w = 0 and z-contour around  z = w.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the right-hand side the notation {AB}(pl)  −k,m+n means the m + n-th Fourier  mode of the local operator that appears as k-th order pole in OPE of A and B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Let us  emphasize that the expression that we derived shows that all the commutation relations  between Fourier modes of local operators are determined solely from the singular part of  the operator product expansion of the two operators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Cylinder  Let us repeat the previous calculations, this time on the cylinder, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' in coordinate y related  to the plane coordinate z by the exponential map,  z = ey.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  Note that for simplicity we do not introduce any signs or imaginary units so in particular  the circles around origin in the complex plane are mapped to at line segments with constant  real part and imaginary part running over an interval of length 2π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The Fourier expansion of a local field A on the cylinder is now  A(cyl)(y) =  �  m∈Z  e−myA(cyl)  m  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  In general these Fourier modes are not equal to those calculated in the complex plane,  A(cyl)  m  ̸= A(pl)  m .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (in general)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  Conformal primary fields  One exception is a conformal primary field A(z) of conformal  dimension h which by definition transforms as  A(z)(z)dzh = A(w)(w)dwh  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  under conformal transformation z = z(w).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Specializing to the exponential map between  the complex plane and cylinder (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10), this gives  A(pl)(z)zh = A(cyl)(y)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  so in this case we indeed have A(cyl)  m  = A(pl)  m  (actually this relation is the reason why Fourier  modes in (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1) are conventionally shifted by h).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' But already the stress-energy tensor T(z)  has more complicated transformation property than (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13) which is responsible for the  shift between the zero mode of T on the complex plane and the zero mode on the cylinder  (the difference after adding the holomorphic and anti-holomorphic contributions being the  Casimir energy).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Derivatives  The Fourier modes of field A and its derivative ∂A are very simply related:  (∂A(cyl))m = −mA(cyl)  m  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  In particular, a zero mode of a total derivative vanishes (which was not true in the case of  complex plane).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 71 –  Normal ordering in terms of Fourier modes  In order to express the (conformal)  normal ordering in terms of Fourier modes on cylinder, we first invert the Fourier expansion  of A:  A(cyl)  m  =  1  2πi  � 2πi  0  emyA(cyl)(y)dy = 1  2π  � 2π  0  eimt+mrA(cyl)(r + it)dt  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  where in the first integral we integrate over a segment of length 2π parallel to the imaginary  axis, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' y = it + r, t ∈ (0, 2π), r = const.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The conformal normal ordered product of fields  on the cylinder is calculated as (assuming A and B to be bosonic)  (A(cyl)B(cyl))(cyl)(x) =  1  2πi  �  x  dy  y − xA(cyl)(y)B(cyl)(x)  =  1  2πi  �  x  dy  ey−x − 1A(cyl)(y)B(cyl)(x)  −  ∞  �  k=1  �  x  Bk  k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' (y − x)k−1A(cyl)(y)B(cyl)(x)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  =  1  2πi  �  x  dy  ey−x − 1A(cyl)(y)B(cyl)(x) −  �  k>0  Bk  k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  A(cyl)B(cyl)�  −k (x)  In order to be able to apply the contour deformation argument, we need the integrand to  be a function globally defined on the cylinder (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' 2π-periodic in the imaginary direction).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  For this reason, in the second equality we replaced a non-periodic function (y − x)−1 by its  periodic version up to a correction that is expressible in terms of singular part of OPE of  A and B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here Bk are the Bernoulli numbers (B1 = − 1  2, B2 = 1  6, B3 = 0, B4 = − 1  30, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The fields are implicitly radially ordered (which in this case means that the field A(x) with  ℜx > ℜy appears to the left of B(y) etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We can now use the contour deformation argument to write the first term as  1  2πi  ��  ℜy>ℜx  −  �  ℜy<ℜx  �  dy  ey−x − 1A(cyl)(y)B(cyl)(x)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  The integral is along the line segment of constant real part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Plugging in the mode expan-  sions, its remains to evaluate the integrals  �  ℜy>ℜx  e−mye−nx  ey−x − 1  dy  2πi =  �  0  m ≥ 0  e−(m+n)x  m ≤ −1  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  �  ℜy<ℜx  e−mye−nx  ey−x − 1  dy  2πi =  �  −e−(m+n)x  m ≥ 0  0  m ≤ −1  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  where we are integrating along a y-contour which is a segment of length 2π parallel with  imaginary axis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Finally, we find the normal ordered product in terms of Fourier modes on  cylinder,  (A(cyl)B(cyl))(cyl)(x) =  �  n∈Z  �  m<0  e−(m+n)xAmBn +  �  n∈Z  �  m≥0  e−(m+n)xBnAm  – 72 –  −  �  k>0  Bk  k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  A(cyl), B(cyl)�  −k (x)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  or  (AB)(cyl)  m  =  �  n<0  A(cyl)  n  Bm−n +  �  n≥0  Bm−nAn −  �  k>0  Bk  k!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' {AB}(cyl)  −k,m .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  We see that unlike for the Fourier modes on the complex plane, here the normal order  depends on the singular part of the OPE of A and B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Just as for the complex plane,  anticommuting fields would have an additional minus sign in the second term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Commutators of Fourier modes  Finally we derive the expression for commutator of  Fourier modes in terms of singular part of operator product expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have  �  A(cyl)  m  , B(cyl)  n  �  =  1  (2πi)2  ���  ℜy>ℜx  −  ��  ℜx>ℜy  �  enx+myA(cyl)(y)B(cyl)(x)  =  � 2πi  0  dx  2πi  �  x  dy  2πienx+myA(cyl)(y)B(cyl)(x)  =  � 2πi  0  dx  2πi  �  x  dy  2πi  �  k>0  enx+my  (y − x)k  �  A(cyl)B(cyl)�  −k (x)  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  =  � 2πi  0  dx  2πi  �  k>0  e(m+n)xmk−1  (k − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  A(cyl)B(cyl)�  −k (x)  =  �  k>0  mk−1  (k − 1)!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  �  A(cyl)B(cyl)�  −k,m+n  In particular, for m = 0 only the first order pole (k = 1) contributes and we have a simple  relation  �  A(cyl)  0  , B(cyl)(x)  �  =  �  A(cyl)B(cyl)�  −1 (x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  An analogous commutator of a zero mode on the plane is more complicated and involves  all of the singular terms of OPE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Example - Virasoro algebra  The stress-energy tensor T(z) has the following operator product expansion with respect  to any choice of complex coordinates  T(z)T(w) =  c/2  (z − w)4 +  2T(w)  (z − w)2 + ∂T(w)  z − w + reg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  Denoting the Fourier modes of T(z) in complex plane by Lm, we can use (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9) to find the  commutator  [Lm, Ln] =  �m + 1  3  �c  21m+n +  �m + 1  1  �  2Lm+n +  �m + 1  0  �  (−m − n − 2)Lm+n  = c(m + 1)m(m − 1)  12  δm+n,0 + (m − n)Lm+n  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  – 73 –  which is the Virasoro algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Denoting the corresponding Fourier modes on the cylinder  by Tm, the commutation relations of these are instead  [Tm, Tn] = m3  6  c  21m+n + 2mTm+n − (m + n)Tm+n  = cm3  12 δm+n,0 + (m − n)Tm+n  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  as follows from (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is the Virasoro algebra on the cylinder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The two commutation  relations are related by the identification  Tm = Lm − c  24δm,0  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  which is a consequence of the transformation property of stress-energy tensor under con-  formal transformations  � dz  dw  �2  T (z)(z) = T (w)(w) − c  12  �� d3z  dw3  � � dz  dw  �−1  − 3  2  � d2z  dw2  �2 � dz  dw  �−2�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  which in the case of exponential map (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10) simplifies to  z2T (cyl)(z) = T (pl)(y) + c  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  To check the expression for Fourier modes of composite fields, let us consider the zero  mode of a local operator (TT)(x) on the cylinder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Using (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22) we find  (TT)(cyl)  0  = T 2  0 + 2  �  m>0  T−mTm +  1  720  c  2 − 1  122T0 + 1  2(∂T)0  = T 2  0 + 2  �  m>0  T−mTm +  c  1440 − 1  6T0  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  = L2  0 + 2  �  m>0  L−mLm − c + 2  12 L0 + c(5c + 22)  2880  which agrees with expressions given in appendix of [3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  As a side comment, observe that the constant term vanishes for c = − 22  5 which is the  Lee-Yang minimal model (related to (A1, A2) Argyres-Douglas theory) and for this value  of central charge (TT)(cyl)  0  vanishes on the primary state if and only if h = 0 and h = − 1  5  which are exactly the two primaries of the Lee-Yang minimal model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  B  Large u expansion of R-matrix  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Mode expansions  Using the results of appendix A, we can find the cylinder Fourier modes of the composite  operators constructed out of local current J− with OPE  J−(z)J−(w) ∼  2α2  0  (z − w)2 + reg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  – 74 –  that enters the large central charge expansion of the instanton R-matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We find using  (A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  (J−J−)m =: J2  − :m −2α2  0  12 δm,0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  (J−(J−J−))m =: J3  − :m −2α2  0  4  : J− :m  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  (J−(J−(J−J−)))m =: J4  − :m −2α2  0  2  : J2  − :m +4α4  0  48 δm,0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  (∂J−∂J−)m =: ∂J−∂J− :m −2α2  0  120δm,0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  where : Jk  − : denotes the creation-annihilation normal ordering and we suppress the subscript  (cyl) associated to Fourier modes on the left-hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Large u expansion of R at N = 1  Here we collect expressions for first coefficients r(j) of the large u expansion of the logarithm  of Maulik-Okounkov R-matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' First five of these were given in [39] in terms of oscillators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Here we write them as zero modes of local currents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this appendix we write J instead of  J− to simplify the notation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' All zero modes are with respect to coordinates on the cylinder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  r(1) = −1  2(JJ)0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  r(2) = 1  6(J(JJ))0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  r(3) = − 1  12(J(J(JJ)))0 + α2  0(1 + 2α2  0)  12  (∂J∂J)0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  r(4) = 1  20(J(J(J(JJ))))0 − α2  0(1 + 2α2  0)  4  (∂J(∂JJ))0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  r(5) = − 1  30(J(J(J(J(JJ)))))0 + α2  0(1 + 2α2  0)  2  (∂J(∂J(JJ)))0  − α4  0(2 + 9α2  0 + 6α4  0)  60  (∂2J∂2J)0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  r(6) = 1  42(J(J(J(J(J(JJ))))))0 − 5α2  0(1 + 2α2  0)  6  (∂J(∂J(J(JJ))))0  + α4  0(2 + 9α2  0 + 6α4  0)  12  (∂2J(∂2JJ))0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  r(7) = − 1  56(J(J(J(J(J(J(JJ)))))))0 + 5α2  0(1 + 2α2  0)  4  (∂J(∂J(J(J(JJ)))))0  − α4  0(2 + 9α2  0 + 6α4  0)  4  (∂2J(∂2J(JJ)))0 + α4  0(9 + 41α2  0 + 26α4  0)  72  (∂J(∂J(∂J∂J)))0  + α6  0(90 + 671α2  0 + 998α4  0 + 360α6  0)  5040  (∂3J∂3J)0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  r(8) = 1  72(J(J(J(J(J(J(J(JJ))))))))0 − 7α2  0(1 + 2α2  0)  4  (∂J(∂J(J(J(J(JJ))))))0  + 7α4  0(2 + 9α2  0 + 6α4  0)  12  (∂2J(∂2J(J(JJ))))0  – 75 –  − 7α4  0(9 + 41α2  0 + 26α4  0)  72  (∂J(∂J(∂J(∂JJ))))0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  − α6  0(90 + 671α2  0 + 998α4  0 + 360α6  0)  720  (∂3J(∂3JJ))0  + α6  0(25 + 186α2  0 + 278α4  0 + 100α6  0)  180  (∂2J(∂2J(∂2J)))0  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Large u expansion of universal R  In this appendix we list expressions of coefficients r(j) of the large central charge expansion  of the logarithm of R(u), see (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have  r(1) = −α0 ¯NT0 − α0N ¯T0 + α0(U1 ¯U1)0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  r(2) = α0 ¯N  2  φ3,0 − α0(T ¯U1)0 + α0(U1 ¯T)0 − α0N  2  ¯φ3,0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  r(3) = α0 ¯N  3  φ4,0 + α0(φ3 ¯U1)0 − 2α0(T ¯T)0 + α0(U1 ¯φ3)0 + Nα0  3  ¯φ4,0  +  ¯N( ¯N − 1)α3  0  12  (∂U1∂U1)0 + N(N − 1)α3  0  12  (∂ ¯U1∂ ¯U1)0  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  − 1  6α0(α2  0N ¯N − α2  0N − α2  0 ¯N − α2  0 − 1)(∂U1∂ ¯U1)0  r(4) = α0 ¯N  4  φ5,0 + α0( ¯U1φ4)0 + 3α0(φ3 ¯T)0 − 3α0(T ¯φ3)0 − α0(U1 ¯φ4)0 − α0N  4  ¯φ5,0  − (N ¯Nα2  0 − 2 ¯Nα2  0 − Nα2  0 − 2α2  0 − 2)α0  4  ( ¯U1∂2T)0 − ( ¯N − 1)α3  0  4  ( ¯U1(∂2U1U1))0  + (N ¯Nα2  0 − 2Nα2  0 − ¯Nα2  0 − 2α2  0 − 2)α0  4  (U1∂2 ¯T)0 + (N − 1)α3  0  4  (U1(∂2 ¯U1 ¯U1))0 (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  − N(N − 1)α3  0  4  ( ¯U1∂2 ¯T)0 +  ¯N( ¯N − 1)α3  0  4  (U1∂2T)0  and more complicated expressions for higher orders.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We defined the local fields  T = −U2 + 1  2(U1U1) + (N − 1)α0  2  ∂U1  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  φ3 = U3 − (U1U2) + 1  3(U1(U1U1)) − (N − 2)α0  2  U ′  2  + (N − 1)α0  2  (U ′  1U1) + N2α2  0 − Nα2  0 + 4α2  0 + 2  12  U ′′  1  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  φ4 = U4 − (U1U3) − 1  2(U2U2) + (U1(U1U2)) − 1  4(U1(U1(U1U1)))  + (N − 2)α0  2  (U1U ′  2) + (N − 1)α0  2  (U ′  1U2) − (N − 1)α0  2  (U ′  1(U1U1))  − (N − 3)α0  2  U ′  3 − N2α2  0 + 2Nα2  0 + 3α2  0 + 3  12  (U ′  1U ′  1)  (B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− N2α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 12α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − 3N + 9  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U ′′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 U1) + N2α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − 3Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 12α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='U ′′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− (N − 1)(2Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 6α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − 2N + 5)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='U ′′′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='φ5 = U5 − (U1U4) − (U2U3) + (U1(U1U3)) + (U1(U2U2)) − (U1(U1(U1U2)))  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='– 76 –  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5(U1(U1(U1(U1U1)))) − (N − 2)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U1(U1U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)) − (N − 1)α0(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1(U1U2))  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ (N − 3)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U1U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3) + (N − 1)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1U3) + (N − 1)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1(U1(U1U1)))  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ (N − 2)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2U2) − (N − 4)α0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 − N2α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − 3Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 22α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U1U ′′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 )  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ N2α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 3Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 8α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1U1)) − N2α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 2Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 6α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + 6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1U ′  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  − N2α2  0 − Nα2  0 + 26α2  0 − 6N + 24  12  (U ′′  1 U2) + (N − 1)(3Nα2  0 + 8α2  0 + 6)α0  6  (U ′′  1 U ′  1)  + N2α2  0 − Nα2  0 + 24α2  0 − 6N + 18  12  (U ′′  1 (U1U1)) + N2α2  0 − 5Nα2  0 + 24α2  0 + 6  12  U ′′  3  + (N − 1)(Nα2  0 + 8α2  0 − N + 3)α0  12  (U ′′′  1 U1) − (N − 2)(Nα2  0 + 6α2  0 + 4)α0  12  U ′′′  2  − N4α4  0 − 16N3α4  0 − 19N2α4  0 + 34Nα4  0 − 144α4  0 − 15N3α2  0 + 5Nα2  0 − 206α2  0 − 48  720  U (4)  1  C  Explicit expressions for ILW Hamiltonians  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  (Quasi-)modular forms  First few Eisenstein series are  E2(q) = 1 − 24  �  m>0  mqm  1 − qm  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  E4(q) = 1 + 240  �  m>0  m3qm  1 − qm  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  E6(q) = 1 − 504  �  m>0  m5qm  1 − qm  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  E8(q) = 1 + 480  �  m>0  m7qm  1 − qm = E4(q)2  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  and satisfy useful relations  q∂qE2 = −E4 − E2  2  12  = −24  �  m>0  m2qm  (1 − qm)2  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  q∂qE4 = −4E6 − E2E4  12  = 240  �  m>0  m4qm  (1 − qm)2  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  q∂qE6 = −6E8 − E2E6  12  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  All Eistenstein series E2k with 2k ≥ 8 are algebraically dependent on the basic ones E2, E4  and E6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  E2 is not modular but only quasi-modular and the ring of modular forms is  generated by E4 and E6 only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Allowing differentiation q∂q as well, we see that everything  can be expressed in terms of E2 only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 77 –  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Calculation of expectation values in auxiliary space  In order to find explicit formulas for ILW Hamiltonians from the universal R-matrix, we  need to take torus expectation values of various quantities in the bosonic Fock space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Here  we list various expectation values of these.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We start with two simple lemmas:  Lemma 1  ⟨O ¯T0⟩q =  �  q∂q − E2  24  �  ⟨O⟩q  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  ⟨O ¯T0⟩qc = q∂q⟨O⟩q  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  Proof: for the first equation, we have  ⟨O¯L0⟩q = q∂q  �  λ q|λ| ⟨¯λ| O |¯λ⟩  �  λ q|λ|  = q∂q  ��  λ q|λ| ⟨¯λ| O |¯λ⟩  �  λ q|λ|  �  +  �  λ q|λ| ⟨¯λ| O |¯λ⟩  �  λ q|λ|  q∂q  �  λ q|λ|  �  λ q|λ|  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  =  �  q∂q + 1 − E2  24  �  ⟨O⟩q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Therefore,  ⟨O ¯T0⟩q = ⟨O¯L0⟩q − 1  24⟨O⟩q =  �  q∂q − E2  24  �  ⟨O⟩q  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  as we wanted to show.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For the second claim, we have simply  ⟨O ¯T0⟩qc ≡ ⟨O ¯T0⟩q − ⟨O⟩q⟨ ¯T0⟩q = q∂q⟨O⟩q  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  Analogously, we have  ⟨ ¯T 2  0 O⟩c ≡ ⟨ ¯T 2  0 O⟩ − ⟨ ¯T 2  0 ⟩⟨O⟩ − 2⟨ ¯T0⟩⟨ ¯T0O⟩ + 2⟨ ¯T0⟩2⟨O⟩  =  �  q ∂  ∂q − E2  24  �2  ⟨O⟩ − E4 − E2  2  288  ⟨O⟩ + E2  12  �  q ∂  ∂q − E2  24  �  ⟨O⟩ + E2  2  576⟨O⟩  =  �  q ∂  ∂q  �2  ⟨O⟩ −  �  q ∂  ∂q  E2  24  �  ⟨O⟩ − E2  12  �  q ∂  ∂q  �  ⟨O⟩ + E2  2  576⟨O⟩  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  − E4 − E2  2  288  ⟨O⟩ + E2  12  �  q ∂  ∂q − E2  24  �  ⟨O⟩ + E2  2  576⟨O⟩  =  �  q ∂  ∂q  �2  ⟨O⟩.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Lemma 2  For two local fields A and B in the left sector (independent of ¯J), we have  ⟨(A ¯J)0(B ¯J)0⟩q =  �  m>0  m  1 − qm A−mBm +  �  m>0  mqm  1 − qm AmB−m  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  ≡  �  m>0  dmA−mBm +  �  m>0  d−mAmB−m  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  – 78 –  where we introduce the derivative  dm ≡  m  1 − qm .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  Proof: first of all, one can show easily by calculation similar to evaluation of ⟨ ¯T0⟩q that  ⟨ ¯Jm ¯J−m⟩q = q∂q log  1  1 − qm =  m  1 − qm = −mq−m  1 − q−m  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  which holds for both positive and negative m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Due to the fact that A and ¯J commute  (have regular OPE), their normal ordered product is just their product (and the same for  A ↔ B) so  ⟨(A ¯J)0(B ¯J)0⟩q =  �  m∈Z  A−mBm⟨ ¯Jm ¯J−m⟩q  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  =  �  m>0  m  1 − qm A−mBm +  �  m>0  mqm  1 − qm AmB−m  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  as we wanted to show.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can in principle normal order the right-hand side,  ⟨(A ¯J)0(B ¯J)0⟩q =  �  m>0  m  1 − qm A−mBm +  �  m>0  mqm  1 − qm B−mAm +  �  m>0  mqm  1 − qm [Am, B−m]  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  As an application of this formula, we have  ⟨(U1 ¯J)0(U1 ¯J)0⟩q =  �  m>0  m1 + qm  1 − qm U1,−mU1,m + N  �  m>0  m2qm  1 − qm .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  Similarly, we have the following correlators  ⟨ ¯Tm ¯T−m⟩ = m(m2 − E2)  12(1 − qm)  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  ⟨ ¯Jm( ¯J( ¯J ¯J))−m⟩ = −  mE2  4(1 − qm)  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  ⟨( ¯J( ¯J ¯J))m ¯J−m⟩ = −  mE2  4(1 − qm)  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  ⟨ ¯Jm ¯Jn ¯T−m−n⟩ =  mn  (1 − qm)(1 − qn)  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  ⟨ ¯J−m ¯Jm ¯J−n ¯Jn⟩ = mnqm(δmn + qn)  (1 − qm)(1 − qn) ,  m, n > 0  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  which lead to analogous formulas as in lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Some properties of dm  The modified derivatives dm satisfy various relations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Their  derivatives are  q∂qdm = dmd−m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  – 79 –  The difference of these derivatives gives an ordinary derivative,  dm − d−m = m  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  while their sum  dm + d−m = m1 + qm  1 − qm  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  is the integral kernel appearing in ILW equation and interpolates between Benjamin-Ono  or Yangian limit and Bahanov-Lukyanov-Zamolodchikov or Kadomtsev-Petviashvili limits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  There are also more complicated identities involving infinite sums such as  �  j∈Z  j̸=0,m  djdm−j = m2 − E2  6  dm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  List of expectation values in auxiliary space  Here is a list of useful expectation values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  ⟨ ¯T0⟩q = −E2  24  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  ⟨ ¯T 2  0 ⟩qc = E4 − E2  2  288  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  ⟨ ¯T 3  0 ⟩qc = −2E6 + 3E2E4 − E3  2  1728  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  ⟨ ¯T 4  0 ⟩qc = 3E2  4 − 8E2E6 + 6E2  2E4 − E4  2  6912  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  ⟨(∂ ¯J∂ ¯J)0⟩q = − 1  120 − 2  �  m>0  m3qm  1 − qm = − E4  120  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  ⟨( ¯J( ¯J( ¯J ¯J)))0⟩q = E2  2  48  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  ⟨( ¯J( ¯J ¯J))0( ¯J( ¯J ¯J))0⟩ = −2E6 − 3E2E4 + 5E3  2  720  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  ⟨( ¯J( ¯J( ¯J ¯J)))0 ¯T0⟩c = −E2E4 + E3  2  288  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='38)  ⟨(∂ ¯J∂ ¯J)0 ¯T0⟩c = E6 − E2E4  360  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='39)  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  Third order ILW Hamiltonian  We need the following expectation values:  ⟨r(3)⟩ = α0  3 φ4,0 − 2α0T0⟨ ¯T0⟩ + Nα0  3  ⟨¯φ4,0⟩ + N(N − 1)α3  0  12  (∂ ¯J∂ ¯J)0  = α0  3 φ4,0 + α0E2  12 T0 − Nα0E2  2  576  − Nα0(1 + α2  0 + Nα2  0)E4  1440  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='40)  ⟨r(1)r(2)⟩sc ≡ 1  2⟨r(1)r(2)⟩ + 1  2⟨r(2)r(1)⟩ − 1  2⟨r(1)⟩⟨r(2)⟩ + 1  2⟨r(2)⟩⟨r(1)⟩  = −α2  0NU1,0⟨ ¯T 2  0 ⟩c − α2  0  2 ⟨(U1 ¯J)0(T ¯J)0⟩c − α2  0  2 ⟨(T ¯J)0(U1 ¯J)0⟩c  – 80 –  = −α2  0NU1,0  E4 − E2  2  288  − α2  0  2  �  m>0  m(1 + qm)  1 − qm  (U1,−mTm + T−mU1,m)  − α2  0  �  m>0  m2qm  1 − qm U1,0  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='41)  1  6⟨r(1)3⟩sc ≡ 1  6⟨r(1)3⟩ − 1  4⟨r(1)2⟩⟨r(1)⟩ − 1  4⟨r(1)⟩⟨r(1)2⟩ + 1  3⟨r(1)⟩3  = −α3  0N3  6  ⟨ ¯T0 ¯T0 ¯T0⟩c + α3  0  12T0⟨(U1 ¯U1)0(U1 ¯U1)0⟩ − α3  0  6 ⟨(U1 ¯U1)0T0(U1 ¯U1)0⟩  + α3  0  12⟨(U1 ¯U1)0(U1 ¯U1)0⟩T0 − α3  0N  3  ⟨ ¯T0(U1 ¯U1)0(U1 ¯U1)0⟩  − α3  0N  6  ⟨(U1 ¯U1)0 ¯T0(U1 ¯U1)0⟩ + α3  0N  2  ⟨ ¯T0⟩⟨(U1 ¯U1)0(U1 ¯U1)0⟩  = −α3  0N3  6  −2E6 + 3E2E4 − E3  2  1728  + α3  0  12⟨(∂U1 ¯U1)0(U1 ¯U1)0⟩  − α3  0  12⟨(U1 ¯U1)0(∂U1 ¯U1)0⟩ − α3  0N  2  ⟨ ¯T0(U1 ¯U1)0(U1 ¯U1)0⟩  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='42)  + α3  0N  2  ⟨ ¯T0⟩⟨(U1 ¯U1)0(U1 ¯U1)0⟩ + α3  0N  6  ⟨(U1 ¯U1)0(∂U1 ¯U1)0⟩  = −α3  0N3  6  −2E6 + 3E2E4 − E3  2  1728  − α3  0N  �  m>0  m2qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m − α3  0N2  2  �  m>0  m3qm  (1 − qm)2  − α3  0(N − 1)  6  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + α3  0N(N − 1)  6  �  m>0  m3qm  1 − qm  Adding everything,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' we finally find  (log Hq)3 = α0  3 φ4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − α2  0  2  �  m>0  m(1 + qm)  1 − qm  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α3  0(N + 2)  12  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m − α3  0N  4  �  m>0  m2(1 + qm)2  (1 − qm)2  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α0E2  12 T0 − α2  0N E4 − E2  2  288  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − α2  0  �  m>0  m2qm  1 − qm U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='43)  + α3  0N3 2E6 − 3E2E4 + E3  2  10368  + α3  0N(N − 1)  6  �  m>0  m3qm  1 − qm  − α3  0N2  2  �  m>0  m3qm  (1 − qm)2 − Nα0(1 + α2  0 + Nα2  0)E4  1440  − Nα0E2  2  576  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5  Fourth order ILW Hamiltonian  ⟨r(4)⟩ = α0  4 φ5,0 − α0E2  8  φ3,0 + α0E2  2  192 U1,0 + α0(1 + α2  0 + Nα2  0)E4  480  U1,0  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44)  1  2⟨r(1)r(3)⟩sc = 1  2  �  ⟨r(1)r(3)⟩ − ⟨r(1)⟩⟨r(3)⟩ + ⟨r(3)r(1)⟩ − ⟨r(3)⟩⟨r(1)⟩  �  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45)  – 81 –  = 2α2  0N⟨ ¯T 2  0 ⟩cT0 + α2  0  2 ⟨(U1 ¯J)0(φ3 ¯J)0⟩ + α2  0  2 ⟨(φ3 ¯J)0(U1 ¯J)0⟩  + α2  0  6 ⟨(U1 ¯J)0(U1( ¯J( ¯J ¯J)))0⟩ + α2  0  6 ⟨(U1( ¯J( ¯J ¯J)))0(U1 ¯J)0⟩  + α2  0N2  12  ⟨ ¯T0( ¯J( ¯J( ¯J ¯J)))0⟩c − α2  0(1 + α2  0 + Nα2  0)N2  12  ⟨ ¯T0(∂ ¯J∂ ¯J)0⟩c  = α2  0  2  �  m>0  m(1 + qm)  1 − qm  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  − α2  0E2  12  �  m>0  m(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0N E4 − E2  2  144  T0 + 2α2  0  �  m>0  m2qm  1 − qm T0  + α2  0  6 (1 + α2  0 + Nα2  0)N  �  m>0  m4qm  1 − qm − α2  0NE2  12  �  m>0  m2qm  1 − qm  + α2  0N2  3456 (−E2E4 + E3  2) − α2  0(1 + α2  0 + Nα2  0)N2  4320  (E6 − E2E4)  1  2⟨r(2)2⟩c = 1  2⟨r(2)2⟩ − 1  2⟨r(2)⟩2  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='46)  = +α2  0  2 ⟨(T ¯J)0(T ¯J)0⟩ + α2  0  2 ⟨(U1 ¯T)0(U1 ¯T)0⟩c + α2  0N2  72  ⟨( ¯J( ¯J ¯J))0( ¯J( ¯J ¯J))0⟩  = +α2  0  2  �  m>0  m(1 + qm)  1 − qm  T−mTm + α2  0  �  m>0  m2qm  1 − qm T0  + α2  0  2  �  m>0  m(m2 − E2)(1 + qm)  12(1 − qm)  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0N2  72  −2E6 − 3E2E4 + 5E3  2  720  + α2  0N  2  �  m>0  m2qm(m2 − E2)  12(1 − qm)  + α2  0N(1 + α2  0 − α2  0N2)  24  �  m>0  m4qm  1 − qm + α2  0  2  E4 − E2  2  288  U 2  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  1  2⟨r(1)2r(2)⟩sc =  �1  6⟨r(1)2r(2)⟩ − 1  4⟨r(1)2⟩⟨r(2)⟩ − 1  4⟨r(1)⟩⟨r(1)r(2)⟩ + 1  3⟨r(1)⟩2⟨r(2)⟩  �  +  �1  6⟨r(1)r(2)r(1)⟩ − 1  4⟨r(1)r(2)⟩⟨r(1)⟩ − 1  4⟨r(1)⟩⟨r(2)r(1)⟩ + 1  3⟨r(1)⟩⟨r(2)⟩⟨r(1)⟩  �  +  �1  6⟨r(2)r(1)2⟩ − 1  4⟨r(2)r(1)⟩⟨r(1)⟩ − 1  4⟨r(2)⟩⟨r(1)2⟩ + 1  3⟨r(2)⟩⟨r(1)⟩2  �  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47)  = −α3  0  12  �  m>0  m2(T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm) + α3  0  6  �  m>0  m3qm  1 − qm U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  − α3  0  6  �  m>0  m2(U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) + α3  0  3  �  m>0  m3qm  1 − qm U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + α3  0N  �  m>0  m2qm  (1 − qm)2 (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) + α3  0N  �  m>0  m3qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  – 82 –  + α3  0N  6  �  m>0  m2(U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) − α3  0N  3  �  m>0  m3qm  1 − qm U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + α3  0N2  2  −2E6 + 3E2E4 − E3  2  1728  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + α3  0  12  �  m,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='n>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−nU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m+n + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m−nU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='n)×  ×  �mn(2 + 2qm+n + qm + qn)  (1 − qm)(1 − qn)  + m(m + n)(2qm + 1 + 2qm+n + q2m+n)  (1 − qm)(1 − qm+n)  + n(m + n)(2qn + 1 + 2qm+n + qm+2n)  (1 − qn)(1 − qm+n)  �  + α3  0U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  m2qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + α3  0N  2  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  m3qm  (1 − qm)2  + α3  0  6 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m − α3  0N  6  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  m3qm  1 − qm  1  24⟨r(1)4⟩ =  � 1  24⟨r(1)4⟩ − 1  12⟨r(1)3⟩⟨r(1)⟩ − 1  12⟨r(1)⟩⟨r(1)3⟩ − 1  8⟨r(1)2⟩2  + 1  6⟨r(1)⟩2⟨r(1)2⟩ + 1  6⟨r(1)⟩⟨r(1)2⟩⟨r(1)⟩ + 1  6⟨r(1)2⟩⟨r(1)⟩2 − 1  4⟨r(1)⟩4�  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48)  = α4  0  24  �  m>0  m3(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m − α4  0N  6  �  m>0  m3(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α4  0N2  2  �  m>0  m3qm(1 + qm)  (1 − qm)3  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + α4  0N2  24  �  m>0  m3(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α4  0N  24  �  m>0  m4qm  1 − qm − α4  0N2  12  �  m>0  m4qm  1 − qm + α4  0N2  6  �  m>0  m4qm  (1 − qm)2  + α4  0N2  24  �  m>0  m4qm(1 + 2qm)  (1 − qm)2  + α4  0N3  24  �  m>0  m4qm  1 − qm − α4  0N3  6  �  m>0  m4qm  (1 − qm)2  + α4  0N3  4  �  m>0  m4qm(1 + qm)  (1 − qm)3  + α4  0N4  24  3E2  4 − 8E2E6 + 6E2  2E4 − E4  2  6912  Where we used the following commutation relations:  [U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m] = m3  6 N(1 + α2  0 + Nα2  0) + 2mT0  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='49)  and  [φ3,0, U1,m] = 2(∂T)m = −2mTm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50)  Adding everything,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' we find the fourth ILW Hamiltonian  (log Hq)4 = +α0  4 φ5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + α2  0  2  �  m>0  m(1 + qm)  1 − qm  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α2  0  2  �  m>0  m(1 + qm)  1 − qm  T−mTm + α3  0(2N − 3)  12  �  m>0  m2(U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  – 83 –  + α3  0N  �  m>0  m2qm  (1 − qm)2 (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α3  0  12  �  m,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='n>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−nU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m+n + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m−nU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='n)×  ×  �mn(2 + 2qm+n + qm + qn)  (1 − qm)(1 − qn)  + m(m + n)(2qm + 1 + 2qm+n + q2m+n)  (1 − qm)(1 − qm+n)  + n(m + n)(2qn + 1 + 2qm+n + qm+2n)  (1 − qn)(1 − qm+n)  �  + α3  0  �  m>0  m2qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + α3  0  6  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + α4  0N2  2  �  m>0  m3qm(1 + qm)  (1 − qm)3  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0(1 + α2  0 − 4α2  0N + α2  0N2)  24  �  m>0  m3(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  − α0E2  8  φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − α2  0E2  8  �  m>0  m(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='51)  + α2  0N E4 − E2  2  144  T0 + 3α2  0  �  m>0  m2qm  1 − qm T0 + α2  0  2  E4 − E2  2  288  U 2  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + 3α3  0N  2  �  m>0  m3qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − α3  0(N − 1)  2  �  m>0  m3qm  1 − qm U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + α3  0N2  2  −2E6 + 3E2E4 − E3  2  1728  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + α0E2  2  192 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + α0(1 + α2  0 + Nα2  0)E4  480  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  + α4  0N3  4  �  m>0  m4qm(1 + qm)  (1 − qm)3  + α4  0N2  24  �  m>0  m4qm(1 + 2qm)  (1 − qm)2  − α4  0N2(N − 1)  6  �  m>0  m4qm  (1 − qm)2 − α2  0NE2  8  �  m>0  m2qm  1 − qm  + α2  0N(3 + 3α2  0 + α2  0N)  12  �  m>0  m4qm  1 − qm  + α2  0N2  3456 (−E2E4 + E3  2) − α2  0(1 + α2  0 + Nα2  0)N2  4320  (E6 − E2E4)  + α2  0N2  72  −2E6 − 3E2E4 + 5E3  2  720  + α4  0N4  24  3E2  4 − 8E2E6 + 6E2  2E4 − E4  2  6912  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6  Lowest weight expectation value  Here we list the eigenvalues of lowest ILW Hamiltonians when acting on the lowest weight  state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We have  (log Hq)1,hw = −α0  �  −u2 + u2  1  2 − N  24  �  + α0NE2  24  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52)  (log Hq)2,hw = α0  2  �  u3 − u1u2 + 1  3u3  1 − u1  12  �  − α0E2  24 u1  – 84 –  + α2  0N2 E4 − E2  2  576  + α2  0N  2  �  m>0  m2qm  1 − qm  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='53)  (log Hq)3,hw = α0  3  �α2  0N2  480 − α2  0N  160 − 7N  960 + u2  1u2 − u4  1  4 + u2  1  8 − u1u3 − u2  2  2 − u2  4 + u4  �  + α0E2  12  �  −u2 + u2  1  2 − N  24  �  − α2  0N E4 − E2  2  288  u1 − α2  0  �  m>0  m2qm  1 − qm u1  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54)  + α3  0N3 2E6 − 3E2E4 + E3  2  10368  + α3  0N(N − 1)  6  E4 − 1  240  − α3  0N2  2  �  m>0  m3qm  (1 − qm)2 − Nα0(1 + α2  0 + Nα2  0)E4  1440  − Nα0E2  2  576  (log Hq)4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='hw = +α0  4  �  u5 − u1u4 − u2u3 + u2  1u3 + u1u2  2 − u3  1u2 + u5  1  5  − u3  2 + u1u2  2  − u3  1  6 − (2α2  0N − 6α2  0 − 7)u1  240  �  − α0E2  8  �  u3 − u1u2 + u3  1  3 − u1  12  �  + α2  0N E4 − E2  2  144  �  −u2 + u2  1  2 − N  24  �  + 3α2  0  �  m>0  m2qm  1 − qm  �  −u2 + u2  1  2 − N  24  �  + α2  0  2  E4 − E2  2  288  u2  1  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='55)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 3α3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m3qm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(1 − qm)2 u1 − α3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0(N − 1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='E4 − 1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='240  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='u1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−2E6 + 3E2E4 − E3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1728  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='u1 + α0E2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='192 u1 + α0(1 + α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0)E4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='480  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='u1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m4qm(1 + qm)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(1 − qm)3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m4qm(1 + 2qm)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(1 − qm)2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− α4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N2(N − 1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m4qm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(1 − qm)2 − α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0NE2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2qm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 − qm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N(3 + 3α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m4qm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 − qm  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3456 (−E2E4 + E3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) − α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0(1 + α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 + Nα2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0)N2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4320  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(E6 − E2E4)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='72  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−2E6 − 3E2E4 + 5E3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='720  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ α4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0N4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3E2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 − 8E2E6 + 6E2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2E4 − E4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6912  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='– 85 –  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='The expectation values of the power sums of Yangian Bethe roots Ok as defined in that we  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='used in this calculation are given by  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='⟨O0⟩ =  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='�  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m>0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='d−m = 1 − E2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='56)  ⟨O1⟩ = α0  2  �  m>0  (1 − dm + d−m)d−m = α0(1 − E2)  48  − α0  2  �  k>0  k2qk  1 − qk  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='57)  ⟨O2  0⟩c =  �  m>0  dmd−m = E4 − E2  2  288  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='58)  ⟨O2⟩ =  �  m>0  �7 + 4α2  0  12  (d3  −m − 2d2  −mdm + d−md2  m) + α2  0  2 d2  −m − 1 + α2  0  2  d−mdm − 1 − 2α2  0  12  d−m  �  = 16α2  0 − 17  2880  + (1 − 2α2  0)E2  288  + (1 + 2α2  0)E4  1440  + E2  2  576 − α2  0  2  �  k>0  k2qk  1 − qk  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59)  ⟨O0O1⟩c = α0  4  �  m>0  (d2  −mdm − d−md2  m + d−mdm) = α0(E4 − E2  2)  576  − α0  2  �  k>0  k3qk  (1 − qk)2  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='60)  ⟨O3  0⟩c =  �  m>0  (d2  −mdm + d−md2  m) = −2E6 + 3E2E4 − E3  2  1728  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='61)  ⟨O3⟩ = −α0(4α2  0 + 17)  1920  + α0E2  192 + α0(1 + 2α2  0)E4  960  + α0E2  2  384  + α0(1 − 2α2  0 + E2)  8  �  k>0  k2qk  1 − qk − α0(1 + α2  0)  4  �  k>0  k4qk  1 − qk  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='62)  ⟨O0O2⟩c =  �  m>0  �7 + 4α2  0  12  (d3  −mdm − 2d2  −md2  m + d−md3  m)  − 1 − α2  0  2  d2  −mdm − 1 + α2  0  2  d−md2  m − 1 − 2α2  0  12  d−mdm  �  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='63)  = −4E6 − E2E4 + 5E3  2  17280  − α2  0(E6 − E2E4)  2160  − (1 − 2α2  0)(E4 − E2  2)  3456  − α2  0  2  �  k>0  k3qk  (1 − qk)2  ⟨O2  1⟩c =  �  m>0  �4 + 3α2  0  12  (d3  −mdm − 2d2  −md2  m + d−md3  m)  − 2 − 3α2  0  2  d2  −mdm − 2 + 3α2  0  2  d−md2  m + α2  0  4 d−mdm  �  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='64)  = −2E6 − 3E2E4 + 5E3  2  25920  + α2  0(E4 − E2  2)  1152  + α2  0(−E6 + E2E4)  2880  − α2  0  2  �  k>0  k3qk  (1 − qk)2  ⟨O2  0O1⟩c = α0  2  �  m>0  (d3  −mdm − d−md3  m + d2  −mdm + d−md2  m)  = −α0(2E6 − 3E2E4 + E3  2)  3456  − α0  2  �  k>0  k4qk(1 + qk)  (1 − qk)3  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='65)  – 86 –  ⟨O4  0⟩c =  �  m>0  (d3  −mdm + 4d2  −md2  m + d−md3  m) = 3E2  4 − 8E2E6 + 6E2  2E4 − E4  2  6912  (C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='66)  D  Level 1 test of FJMM  In this appendix we make another test of Feigin-Jimbo-Miwa-Mukhin formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In the main  text we were calculating the individual terms of the asymptotic expansions at u → ∞ to  all orders in q, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' our formulas were perturbative in u but exact in q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' On the other hand,  the matrix elements of R in the Fock representations can be evaluated as exact functions  of u (which are up to an overall normalization just rational functions).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The test that we want to do here will be to calculate the exact eigenvalue of Hq(u) on  level 1 excited state |□⟩ in free boson Fock space (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' N = 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The result is expressed as  a sum over Young diagrams labeling states in the auxiliary space, but the summand will  have slightly different structure than in FJMM formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The strategy is the same one that  we followed in section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3 when calculating the vacuum eigenvalue of Hq(u): we need to  evaluate  1  �  λ q|λ|  �  λ  q|λ| ⟨□| ⊗ ⟨λ| R(u) |□⟩ ⊗ |λ⟩ ,  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  therefore it is enough to find spectrum of the operator  ⟨□| R(u) |□⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  acting on the auxiliary Fock space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Yangian algebra from R-matrix and useful identity  Matrix elements of R-matrix between simple Fock states such as (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) are exactly what  leads to Yangian currents such as ψ(u), e(u) and f(u) [39, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In this section we will review  this construction mainly to fix the notation and also derive an identity (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47) following [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  This identity is exactly what allows us to understand the spectrum of (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We start with (N = 1, ¯N = 1) R-matrix normalized such that it acts on the vacuum  as identity and at level one we have  R(u) |□⟩ ⊗ |0⟩ =  u  u + ϵ3  |□⟩ ⊗ |0⟩ +  ϵ3  u + ϵ3  |0⟩ ⊗ |□⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  R(u) |0⟩ ⊗ |□⟩ =  ϵ3  u + ϵ3  |□⟩ ⊗ |0⟩ +  u  u + ϵ3  |0⟩ ⊗ |□⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  ⟨□| ⊗ ⟨0| R(u) =  u  u + ϵ3  ⟨□| ⊗ ⟨0| +  ϵ3  u + ϵ3  ⟨0| ⊗ ⟨□|  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  ⟨0| ⊗ ⟨□| R(u) =  ϵ3  u + ϵ3  ⟨□| ⊗ ⟨0| +  u  u + ϵ3  ⟨0| ⊗ ⟨□|  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  As explained in [39], these matrix elements can be evaluated easily from the definition (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  In the following, we will study matrix elements of R-matrix with auxiliary space being  one of single free boson (Heisenberg algebra Fock space) while the quantum space will be  a general one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We need to choose which of the two spaces we choose as the auxiliary space  (the space where we take the matrix elements) and which one is the quantum space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We will  – 87 –  follow the convention of the main text, taking the right (barred) space as the auxiliary space  and the left space as the quantum space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' This is the convention used in [41] and the opposite  of the one used in [39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' For calculation of (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2) it would actually be more convenient to  use the opposite convention, but with the current choice we can more easily compare to the  main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Both conventions are exchanged by taking u → −u or R(u) → R(u)−1 so we  can easily obtain results for the other choice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We can now define (see sections 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5 and 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6 in [39])  H(u) = ⟨0|A RQA(u) |0⟩A  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  E(u) = ⟨0|A RQA(u) |□⟩A  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  F(u) = ⟨□|A RQA(u) |0⟩A  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  and  e(u) = H(u)−1E(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  f(u) = F(u)H(u)−1  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  which differs from the conventions of [39] only by an overall constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Consider now three  spaces, auxiliary spaces HA and HB and the quantum space HQ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The Yang-Baxter equation  for such three spaces reads  RQA(u)RQB(v)RAB(v − u) = RAB(v − u)RQB(v)RQA(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  Level 0 → 0 relations  Taking the vacuum-to-vacuum matrix element in auxiliary Fock  spaces we find immediately  ⟨0|A ⟨0|B RQA(u)RQB(v)RAB(v − u) |0⟩A |0⟩B =  = ⟨0|A ⟨0|B RAB(v − u)RQB(v)RQA(u) |0⟩A |0⟩B  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  or in other words  ⟨0|A RQA(u) |0⟩A ⟨0|B RQB(v) |0⟩B = ⟨0|B RQB(v) |0⟩B ⟨0|A RQA(u) |0⟩A  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  which is by definition  H(u)H(v) = H(v)H(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  We used the fact that the R-matrix used in this section is normalized such that it preserves  the vacuum state,  RAB(u) |0⟩A |0⟩B = |0⟩A |0⟩B  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  ⟨0|A ⟨0|B RAB(u) = ⟨0|A ⟨0|B .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  By taking the vacuum-to-vacuum matrix element in the auxiliary space we found a gen-  erating function of Yangian Hamiltonians, discovering one of the integrable structures of  W1+∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Let us now turn to ladder operators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  – 88 –  Level 0 ↔ 1 relations  Taking matrix elements between vacuum and level 1 state in the  auxiliary space (4 matrix elements), we find 2 equations for creation operator  ⟨•, •| RQA(u)RQB(v)RAB(v − u) |□, •⟩ = ⟨•, •| RAB(v − u)RQB(v)RQA(u) |□, •⟩ (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  ⟨•, •| RQA(u)RQB(v)RAB(v − u) |•, □⟩ = ⟨•, •| RAB(v − u)RQB(v)RQA(u) |•, □⟩ (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  or explicitly  (u − v)E(u)H(v) − ϵ3H(u)E(v) = (u − v − ϵ3)H(v)E(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  −ϵ3E(u)H(v) + (u − v)H(u)E(v) = (u − v − ϵ3)E(v)H(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  These two equations are not independent: taking for example the first equation as it is  and the same equation with u ↔ v exchanged, we can eliminate from these two equations  H(v)E(u) and the resulting quantities satisfy the second equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' In fact, we have four  different ways of ordering H and E evaluated at u and v so there are four different equations  with one of these quantities missing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Multiplying the first equation in (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20) by H(u)−1  from the left and using the commutativity of H as well as the definition of e(u) we can  write equivalently  (u − v)e(u)H(v) − ϵ3E(v) = (u − v − ϵ3)H(v)e(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  Multiplying this from the left by H(v)−1, we find  (u − v − ϵ3)e(u) = (u − v)H(v)−1e(u)H(v) − ϵ3e(v).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  Sending v → u − ϵ3,  e(u + ϵ3)H(u) = H(u)e(u) = E(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  In particular, we find  e(u) = H(u)−1E(u) = E(u − ϵ3)H(u − ϵ3)−1  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  For the annihilation operators, we have the following 2 equations  ⟨□, •| RQA(u)RQB(v)RAB(v − u) |•, •⟩ = ⟨□, •| RAB(v − u)RQB(v)RQA(u) |•, •⟩ (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  ⟨•, □| RQA(u)RQB(v)RAB(v − u) |•, •⟩ = ⟨•, □| RAB(v − u)RQB(v)RQA(u) |•, •⟩ (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  or explicitly  (u − v − ϵ3)F(u)H(v) = (u − v)H(v)F(u) − ϵ3F(v)H(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  (u − v − ϵ3)H(u)F(v) = −ϵ3H(v)F(u) + (u − v)F(v)H(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  Level 1 → 1 relations  Taking the matrix elements between level 1 states in the auxiliary  space (4 matrix elements in total), we find equations  ⟨□, •| RQA(u)RQB(v)RAB(v − u) |□, •⟩ = ⟨□, •| RAB(v − u)RQB(v)RQA(u) |□, •⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  – 89 –  ⟨•, □| RQA(u)RQB(v)RAB(v − u) |□, •⟩ = ⟨•, □| RAB(v − u)RQB(v)RQA(u) |□, •⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  ⟨□, •| RQA(u)RQB(v)RAB(v − u) |•, □⟩ = ⟨□, •| RAB(v − u)RQB(v)RQA(u) |•, □⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  ⟨•, □| RQA(u)RQB(v)RAB(v − u) |•, □⟩ = ⟨•, □| RAB(v − u)RQB(v)RQA(u) |•, □⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  Using now the explicit expressions for matrix elements of RAB (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3), we simplify this to  (u − v) [H(v), L□,□(u)] = −ϵ3 (F(u)E(v) − F(v)E(u))  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  (u − v) [E(u), F(v)] = −ϵ3 (H(v)L□,□(u) − H(u)L□,□(v))  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  (u − v) [E(v), F(u)] = −ϵ3 (L□,□(u)H(v) − L□,□(v)H(u))  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  (u − v) [H(u), L□,□(v)] = −ϵ3 (E(v)F(u) − E(u)F(v))  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='37)  where  L□,□(u) ≡ ⟨□|A RQA(u) |□⟩A .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='38)  Let us now construct the ψ operator following [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We start with the equation (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36) and  write it as  (u−v)E(v)H−1(v)H(v)F(u)−(u−v)F(u)H−1(u)H(u)E(v) = −ϵ3 (L□,□(u)H(v) − L□,□(v)H(u))  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='39)  We now use (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28) and (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21) and find  − ϵ3L□,□(u)H(v) + ϵ3L□,□(v)H(u) = ϵ3E(v)H−1(v)F(v)H(u) − ϵ3F(u)H−1(u)E(u)H(v)  + (u − v − ϵ3)E(v)H−1(v)F(u)H(v) − (u − v − ϵ3)F(u)H−1(u)E(v)H(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='40)  Multiplying by H−1(u)H−1(v) from the right and using the definition of e(u) and f(u),  −ϵ3L□,□(u)H−1(u)+ϵ3L□,□(v)H−1(v) = ϵ3E(v)H−1(v)F(v)H−1(v)−ϵ3F(u)H−1(u)E(u)H−1(u)  + (u − v − ϵ3)E(v)H−1(v)F(u)H−1(u) − (u − v − ϵ3)F(u)H−1(u)E(v)H−1(v)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='41)  Expressing terms proportional to (u−v−ϵ3) in terms of f(u) and e(u+ϵ3) and rearranging  the result, we see that  −  ϵ3  u − v − ϵ3  �  L□,□(u)H−1(u) − L□,□(v)H−1(v) + E(v)H−1(v)F(v)H−1(v)  − F(u)H−1(u)E(u)H−1(u)  �  = [e(v + ϵ3), f(u)] .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='42)  Shifting v → v − ϵ3 (and renaming u and v) we finally find  (u − v) [e(u), f(v)] = −ϵ3  �  ψ(u) − ˜ψ(v)  �  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='43)  where  ψ(u + ϵ3) ≡ L□,□(u)H−1(u) − E(u)H−1(u)F(u)H−1(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44)  – 90 –  ˜ψ(u) ≡ L□,□(u)H−1(u) − F(u)H−1(u)E(u)H−1(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45)  Choosing u = v, the left-hand side vanishes while the form of the right-hand side implies a  consistency relation  ψ(u) = ˜ψ(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='46)  which can equivalently be written as  e(u)f(u − ϵ3) − f(u)e(u + ϵ3) = L□,□(u − ϵ3)H−1(u − ϵ3) − L□,□(u)H−1(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='47)  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Level 1 eigenvalue of Hq(u)  Let us now restrict to N = 1 = ¯N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The spectrum of H(u) and ψ(u) are given by the usual  Yangian expressions  H(u) ↔  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='48)  and  ψ(u) ↔ ψλ(u) ≡ u − ϵ3  u  ×  �  □∈λ  (u − ϵ□ + ϵ1)(u − ϵ□ + ϵ2)(u − ϵ□ + ϵ3)  (u − ϵ□ − ϵ1)(u − ϵ□ − ϵ2)(u − ϵ□ − ϵ3)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='49)  where λ is a Young diagram labeling the common eigenstate of H(u) and ψ(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  The relations that we just found allow us to calculate the matrix elements of L□,□(u):  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='44)-(D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='45) can be written as  L□,□(u) = [ψ(u) + f(u)e(u + ϵ3)] H(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='50)  = [ψ(u + ϵ3) + e(u + ϵ3)f(u)] H(u)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='51)  Taking the diagonal matrix element of the first formula, between the eigenstate |λ⟩ of ψ(u),  we find  ⟨λ| L□,□(u) |λ⟩ =  �  �ψλ(u) + #  �  □∈λ+  F(λ + □ → λ)E(λ → λ + □)  (u − ϵ□)(u − ϵ□ + ϵ3)  �  � ×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  =  �  �ψλ(u) − ϵ3  �  □∈λ+  resu→ϵ□ ψλ(u)  (u − ϵ□)(u − ϵ□ + ϵ3)  �  � ×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52)  In the second line we used the fact that the product of creation and annihilation amplitudes  can be expressed in terms of the residue of the generating function ψλ(u) [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Analogously,  the second formula implies  ⟨λ| L□,□(u) |λ⟩ =  �  �ψλ(u + ϵ3) + #  �  □∈λ−  F(λ → λ − □)E(λ − □ → λ)  (u − ϵ□)(u − ϵ□ + ϵ3)  �  � ×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  =  �  �ψλ(u + ϵ3) + ϵ3  �  □∈λ−  resu→ϵ□ ψλ(u)  (u − ϵ□)(u − ϵ□ + ϵ3)  �  � ×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='53)  – 91 –  We can now use the partial fraction expansion  1  (u − ϵ□)(u − ϵ□ + ϵ3) = 1  ϵ3  1  u − ϵ□  − 1  ϵ3  1  u − ϵ□ + ϵ3  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='54)  as well as the fact that ψλ(u) is determined once we know the positions of its simple poles  and the corresponding residues,  ψλ(u) = 1 +  �  □∈λ+  resu→ϵ□ ψλ(u)  u − ϵ□  +  �  □∈λ−  resu→ϵ□ ψλ(u)  u − ϵ□  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='55)  Here we used the shell-formula [27], the fact that ψλ(u) has only simple poles and these  poles are at positions of boxes which can be added or removed consistently with the Young  diagram rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We also used the fact that the value of ψλ(u) at infinity is equal to 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Plugging this into (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='52), we finally find  ⟨λ| L□,□(u) |λ⟩ =  �  �1 +  �  □∈λ+  resu→ϵ□ ψλ(u)  u + ϵ3 − ϵ□  +  �  □∈λ−  resu→ϵ□ ψλ(u)  u − ϵ□  �  � ×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='56)  Using the second formula for L□,□(u) would lead to the same result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  We see that the  diagonal matrix element of L□,□(u) between eigenstates of Yangian Hamiltonians is up to  a contribution from H(u) eigenvalue given by decomposing ψλ(u) into partial fractions and  shifting the poles associated to addable boxes by −ϵ3 while leaving the poles associated to  removable boxes intact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We can now write the formula for Hq(u) eigenvalue at level 1 as  Hq(u) ↔  1  �  λ q|λ|  �  λ  q|λ|  �  �1 +  �  □∈λ+  resu→ϵ□ ψλ(u)  u − ϵ□ + ϵ3  +  �  □∈λ−  resu→ϵ□ ψλ(u)  u − ϵ□  �  �×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='57)  which is a closed form formula valid exactly to all orders in u.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Now we can compare this eigenvalue with the FJMM formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  More precisely, we  calculate  X = ⟨□| Hq(u) |□⟩ ×  �  λ q|λ| × �  □∈λ  u−ϵ□  u−ϵ□+ϵ3  ⟨0| Hq(u) |0⟩  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='58)  in two different ways (the second factor is introduced to fix the normalization).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' From the  derivation in this appendix, we have  X =  �  λ  q|λ|  �  �1 +  �  □∈λ+  resu→ϵ□ ψλ(u)  u − ϵ□ + ϵ3  +  �  □∈λ−  resu→ϵ□ ψλ(u)  u − ϵ□  �  � ×  �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59)  On the other hand, from BAE we see that there is only one Bethe root equal to  x = − ϵ3q  1 − q  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='60)  – 92 –  and the FJMM formula takes the form  X =  u − x  u − x + ϵ3  �  λ  q|λ| �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  ϕ(u − x − ϵ□ + ϵ3)  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='61)  =  �  λ  q|λ|ψλ  �  u +  ϵ3  1 − q  � �  □∈λ  u − ϵ□  u − ϵ□ + ϵ3  (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='62)  Both formulas are exact to all orders in u and can be compared perturbatively in small q  expansion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' We checked that they agree to order O(q27).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' It is interesting that the effect of  splitting the poles corresponding to addable and removable boxes and shifting the addable  boxes by −ϵ3 in (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='59) is equivalent to translating the argument of ψλ(u) by q-dependent  Bethe root as in (D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='61).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  E  Expansions of ILW Hamiltonians in the local limit  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  ILW Hamiltonians with rational matrix elements  Here we summarize the ILW conserved quantities obtained from (log H)j by change of  normalization and more importantly subtraction of the transcendental and central terms:  A1 = T0  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  A2 = −1  2φ3,0 − α0  2  �  m>0  m1 + qm  1 − qm U1,−mU1,m  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  A3 = −1  3φ4,0 + α0  2  �  m>0  m(1 + qm)  1 − qm  (U1,−mTm + T−mU1,m)  − α2  0(N + 2)  12  �  m>0  m2U1,−mU1,m + α2  0N  4  �  m>0  m2(1 + qm)2  (1 − qm)2  U1,−mU1,m  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  A4 = −1  4φ5,0 − α0  2  �  m>0  m(1 + qm)  1 − qm  (U1,−mφ3,m + φ3,−mU1,m)  − α0  2  �  m>0  m(1 + qm)  1 − qm  T−mTm − α2  0(2N − 3)  12  �  m>0  m2(U1,−mTm + T−mU1,m)  − α2  0N  �  m>0  m2qm  (1 − qm)2 (U1,−mTm + T−mU1,m)  − α2  0  12  �  m1,m2>0  (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)×  ×  �  2dm1dm2 + d−m1dm2 + dm1d−m2 + 2d−m1d−m2  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  + dm1dm1+m2 + 2d−m1dm1+m2 + 2dm1d−m1−m2 + d−m1d−m1−m2  + dm2dm1+m2 + 2d−m2dm1+m2 + 2dm2d−m1−m2 + d−m2d−m1−m2  �  − α2  0  �  m>0  m2qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − α2  0  6  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  – 93 –  − α3  0N2  2  �  m>0  m3qm(1 + qm)  (1 − qm)3  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  − α0(1 + α2  0 − 4α2  0N + α2  0N2)  24  �  m>0  m3(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  A5 = −1  5φ6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0 − α0  2  �  m>0  m(1 + qm)  1 − qm  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m ˜φ4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + ˜φ4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α0  2  �  m>0  m(1 + qm)  1 − qm  (T−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm)  + α2  0(N − 2)  6  �  m>0  m2(U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α2  0(N − 2)  6  �  m>0  m2T−mTm + α2  0N  �  m>0  m2qm  (1 − qm)2 T−mTm  + α0  12  �  m>0  m3(1 + qm)  1 − qm  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + (N − 1)(N − 2)α3  0  24  �  m>0  m3(1 + qm)  1 − qm  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α3  0N2  2  �  m>0  m3qm(1 + qm)  (1 − qm)3  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α2  0N  �  m>0  m2qm  (1 − qm)2 (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  + α4  0N3  6  �  m>0  m4qm(1 + 4qm + q2m)  (1 − qm)4  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0N(1 + α2  0 + Nα2  0)  36  �  m>0  m4(1 + 4qm + q2m)  (1 − qm)2  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0N  4  �  m>0  m4qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α4  0N(N2 − 4N + 1)  12  �  m>0  m4qm  (1 − qm)2 U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0  72(3N + α2  0 + 2Nα2  0 + N2α2  0)  �  m>0  m4U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α4  0(N − 1)3  120  �  m>0  m4U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α3  0N  6  I4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3 + α4  0(N − 1)  240  I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1 + α3  0  24I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2 + α3  0N  144 I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  − α3  0(N − 1)  24  I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5 + α2  0  3 I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4 + α2  0  6 I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6  – 94 –  where  I4,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3 = 3  2  �  m1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2 + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2) ×  ×  �  dm1d−m1dm2 + dm1d−m1d−m2 + dm1dm2d−m2 + d−m1dm2d−m2 + dm1d−m1dm1+m2  + dm1d−m1d−m1−m2 + dm2d−m2dm1+m2 + dm2d−m2d−m1−m2 + dm1dm1+m2d−m1−m2  + d−m1dm1+m2d−m1−m2 + dm2dm1+m2d−m1−m2 + d−m2dm1+m2d−m1−m2  �  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  + 6U1,0  �  m>0  (d2  md−m + dmd2  −m)U1,−mU1,m  I5,1 = −8N  �  m>0  m4(2 + qm + 2q2m)  (1 − qm)2  U1,−mU1,m  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  I5,2 = −  �  m1,m2>0  (m2  1 + m1m2 + m2  2)(dm1+m2 + d−m1−m2 + dm1 + d−m1 + dm2 + d−m2)×  × (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  − 2N  �  m>0  m3(1 + qm)  1 − qm  (T−mU1,m + U1,−mTm) − 4U1,0  �  m>0  m3(1 + qm)  1 − qm  U1,−mU1,m  I5,3 = 6  �  m1,m2>0  �  dm1dm2dm1+m2 + d−m1dm2dm1+m2 + dm1d−m2dm1+m2 + d−m1dm2d−m1−m2  + dm1d−m2d−m1−m2 + d−m1d−m2d−m1−m2 + 3d−m1d−m2dm1+m2 + 3dm1dm2d−m1−m2  �  ×  × (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  I5,4 =  �  m1,m2>0  �  dm1+m2dm2 + 2dm1+m2d−m2 + 2d−m1−m2dm2 + d−m1−m2d−m2  �  ×  ×  �  U1,−m2T−m1U1,m1+m2 + U1,−m1−m2Tm1U1,m2  �  +  �  m1,m2>0  �  dm1dm2 + 1  2dm1d−m2 + 1  2d−m1dm2 + d−m1d−m2  �  ×  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  ×  �  T−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2Tm1+m2  �  +  �  m>0  � 6m2qm  (1 − qm)2 + m2  �  U1,−mT0U1,m  I5,5 = 1  2  �  m1,m2>0  (U1,−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2U1,m1+m2)×  ×  �  − 2m2  1d−m1 − 2m2  2d−m2 − 8m1m2dm1 − 8m1m2dm2 − 8m2  2dm1 − 8m2  1dm2  + 7m2  1m2 + 7m1m2  2 − 2(m1 − m2)2dm1+m2  �  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  − 2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  m3(1 + qm)  1 − qm  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  I5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6 =  �  m1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2>0  �  m2(m1 + m2)(1 + 2qm2 + 2qm1+m2 + qm1+2m2)  (1 − qm2)(1 − qm1+m2)  ×  – 95 –  ×  �  T−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2 + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m2Tm1+m2  + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1Tm2 + T−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2  �  + m1m2(2 + qm1 + qm2 + 2qm1+m2)  (1 − qm1)(1 − qm2)  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1Tm2 + T−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2)  − 3  m1m2qm1(1 + qm2)  (1 − qm1)(1 − qm1+m2)  �  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2 [U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Tm2] + [T−m2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1] U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2  ��  − 1  6  �  m>0  m4U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + 1  60  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  + 6U1,0  �  m>0  m2qm  (1 − qm)2 (U1,−mTm + T−mU1,m) + U1,0  �  m>0  m2(U1,−mTm + T−mU1,m)  These quantities have matrix elements which are manifestly rational functions of q with  poles only at roots of unity, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' there are no transcendental terms such as the Eisenstein  series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Their spectra in terms of solutions of Bethe ansatz equations are given by:  A1 ⇝ p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='13)  A2 ⇝ p1 − α0  2 p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='14)  A3 ⇝ p2 − α0p1 + 1 + 4α2  0  12  p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='15)  A4 ⇝ p3 − 3α0  2 p2 + 1 + 4α2  0  4  p1 − α0(1 + 2α2  0)  8  p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='16)  A5 ⇝ p4 − 2α0p3 + 1 + 4α2  0  2  p2 − α0(1 + 2α2  0)  2  p1 + 9 + 114α2  0 − 4α2  0N + 144α4  0  720  p0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='17)  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Local expansion of conserved quantities  Here we list the expansion of Aj as q → 1:  A2 ∼ − α0  1 − q  �  m>0  U1,−mU1,m +  �  − 1  2φ3,0 + α0  2  �  m>0  U1,−mU1,m  �  + (1 − q)α0  12  �  m>0  (1 − m2)U1,−mU1,m + O((1 − q)2)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='18)  A3 ∼  Nα2  0  (1 − q)2  �  m>0  U1,−mU1,m +  1  1 − q  �  α0  �  m>0  (U1,−mTm + T−mU1,m) − Nα2  0  �  m>0  U1,−mU1,m  �  +  �  − 1  3φ4,0 − α0  2  �  m>0  (U1,−mTm + T−mU1,m) − α2  0(N + 2)  12  �  m>0  m2U1,−mU1,m  + Nα2  0  12  �  m>0  (1 + 2m2)U1,−mU1,m  �  + O((1 − q)1)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='19)  A4 ∼ − N2α3  0  (1 − q)3  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  – 96 –  +  1  (1 − q)2  �  − Nα2  0  �  m>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) − α2  0U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  − 3α2  0  2  �  m1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2 + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2) + 3N2α3  0  2  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  �  +  1  1 − q  �  − α0  �  m>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) − α0  �  m>0  T−mTm  + Nα2  0  �  m>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) − α0(1 + α2  0 − 4α2  0N + α2  0N2)  12  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + 3α2  0  2  �  m1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2 + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2)  + α2  0U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m − N2α3  0  2  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  �  + O((1 − q)0)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='20)  A5 ∼ + α4  0N3  (1 − q)4  �  m>0  U1,−mU1,m  +  1  (1 − q)3  �  α3  0N2 �  m>0  (T−mU1,m + U1,−mTm) + 2α3  0NU1,0  �  m>0  U1,−mU1,m  + 7α3  0N  2  �  m1,m2>0  (U1,−m1U1,−m2U1,m1+m2 + U1,−m1−m2U1,m1U1,m2)  − 2α4  0N3 �  m>0  U1,−mU1,m  �  1  (1 − q)2  �  + 2α2  0  �  m1,m2>0  (T−m1−m2U1,m1U1,m2 + U1,−m1U1,−m2Tm1+m2)  + 2α2  0  �  m1,m2>0  (U1,−m2T−m1U1,m1+m2 + U1,−m1−m2Tm1U1,m2)  + 2α2  0  �  m1,m2>0  (T−m2U1,−m1U1,m1+m2 + U1,−m1−m2U1,m1Tm2)  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='21)  − 21α3  0N  4  �  m1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1+m2 + U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−m1−m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m1U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m2)  + 2α2  0  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mT0U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + α2  0N  �  m>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mφ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + φ3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + α2  0N  �  m>0  T−mTm − 3α3  0NU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m − α2  0  3  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  + α2  0U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='0  �  m>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m) − 3α3  0N2  2  �  m>0  (U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mTm + T−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m)  + 5α2  0N  12  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + 5α4  0N  12  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  − α4  0N2  3  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + α4  0N3  12  �  m>0  m2U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  – 97 –  + α2  0  3  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m + 7α4  0N3  6  �  m>0  U1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='−mU1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='m  �  + O((1 − q)−1)  Linear combinations of Aj that are finite in q → 1 limit  B1 ≡ A1  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='22)  B2 ≡ lim  q→1 [(1 − q)A2]  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='23)  B3 ≡ lim  q→1 [(1 − q)A3 + α0NA2]  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='24)  B4 ≡ lim  q→1  �  (1 − q)2A4 + (1 − q)α0NA3  �  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='25)  B5 ≡ lim  q→1  �  (1 − q)2A5 + (1 − q)7α0N  3  A4 + 4α2  0N2  3  A3 + α3  0N3  6  A2 − α2  0Nu1  3  A2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='26)  In terms of mode operators, these are given by  B1 = T0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='27)  B2 = −α0  2 (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='28)  B3 = −α0N  2  W3,0 − α0U1,0T0 + α0  3N (U1(U1U1))0 − α2  0N  4  (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='29)  B4 = −α2  0  2 (U1(U1U1))0 + α2  0U1,0(U1U1)0 + α3  0N2  4  (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='30)  B5 = −4α2  0N2  9  �  W4,0 −  3(N − 3)(α2  0N2 + 3α2  0N − 9)  2N(5α2  0N3 − 5α2  0N − 5N − 17)(T∞T∞)0  �  + α2  0  2N  �  (U1(U1(U1U1)))0 − N(U ′  1U ′  1)0  �  + 2α2  0N  3  T 2  0 − α2  0T0(U1U1)0  + 3α2  0N  2  U1,0W3,0 − α3  0N3  12  W3,0  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='31)  − α2  0  N U1,0(U1(U1U1))0 − 19α3  0N  36  (U1(U1U1))0  + 2α2  0U 2  1,0T0 − α3  0N2  6  U1,0T0 − α2  0N  4  T0  + 4α3  0N  3  U1,0(U1U1)0 + α2  0(36 + 7α2  0N3)  72  (U1U1)0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  Their spectra in terms of Bethe roots are given by  B1 ⇝ p0,0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='32)  B2 ⇝ p1,−1 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='33)  B3 ⇝ p2,−1 + α0Np1,0 − α0p1,−1 − α2  0N  2  p0,0 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='34)  B4 ⇝ p3,−2 + α0Np2,−1 + α2  0N  2  p1,−1 + hw.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='35)  – 98 –  B5 ⇝ p4,−2 + 7α0N  3  p3,−1 + 4α2  0N2  3  p2,0 − 2α0p3,−2 − 7α2  0N  2  p2,−1  + α3  0N2(N − 8)  6  p1,0 − α2  0N  3  u1p1,0 + α0N(1 + 4α2  0)  12  p1,−1  + α2  0N2(4 + 16α2  0 − 3α2  0N)  36  p0,0 + α3  0N  6  u1p0,0  (E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='36)  F  Solutions of Bethe ansatz equations  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Lee-Yang, ∆ = 0, level 3  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1  Resultant  The factor of resultant which gives all 15 physical roots corresponding to 5 states at level  3 in ∆ = 0 representation of Lee-Yang is of the form  15  �  j=0  βjxj  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='with  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β15 = (q − 1)10(q + 1)2(q2 + q + 1)3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β14 = −3(q − 1)9(q + 1)(q2 + q + 1)2(33q4 + 43q3 + 28q2 + 13q + 3)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β13 = +2(q − 1)8(q2 + q + 1)(2233q8 + 5861q7 + 7678q6 + 6703q5 + 4118q4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 1915q3 + 622q2 + 65q − 35)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β12 = −6(q − 1)7(20307q11 + 60224q10 + 99023q9 + 108981q8 + 87774q7 + 55299q6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 26595q5 + 8604q4 + 951q3 − 687q2 − 434q − 77)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β11 = +3(q − 1)6(749783q12 + 1744223q11 + 2365345q10 + 2212756q9 + 1574487q8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 880113q7 + 336042q6 + 35985q5 − 44217q4 − 37388q3 − 16847q2 − 3361q + 839)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β10 = −9(q − 1)5(3308679q13 + 5646690q12 + 6135516q11 + 4858939q10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 2992059q9 + 1255144q8 + 131899q7 − 313931q6 − 287540q5 − 159815q4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 52583q3 − 6224q2 + 5010q + 781)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='(F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β9 = +2(q − 1)4(146080348q14 + 161581637q13 + 135923944q12 + 92019809q11  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 42057082q10 + 1378169q9 − 15764754q8 − 17393766q7 − 11748774q6 − 4558375q5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 907046q4 + 94313q3 + 226048q2 + 113861q − 23456)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β8 = −12(q − 1)3(180333417q15 + 94388201q14 + 61100585q13 + 37723050q12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 47534q11 − 19473224q10 − 24531861q9 − 17036862q8 − 9470139q7 − 1708392q6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 40666q5 + 598774q4 + 313866q3 + 155033q2 − 55000q + 300)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β7 = +8(q − 1)2(1525470224q16 − 67057602q15 + 58007498q14 + 64468027q13  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 127940362q12 − 159580082q11 − 206469540q10 − 63924311q9 − 23482788q8  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 977641q7 + 9511632q6 + 7954486q5 + 2154422q4 + 568675q3 − 139810q2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 191490q + 40100)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='– 99 –  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β6 = −48(q − 1)(1091911035q17 − 655148860q16 − 7896247q15 + 25788450q14  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 29750149q13 − 132857401q12 − 117530061q11 + 20865566q10 + 14616293q9  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 2642898q8 + 15160759q7 + 2887639q6 + 1689999q5 − 275210q4 + 195565q3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 378795q2 + 125350q − 12875)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β5 = +288(590434004q18 − 679495775q17 + 105467922q16 + 57781429q15  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 59562920q14 − 175016546q13 + 30903476q12 + 1357527q11 + 33182072q10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 9897385q9 + 7510916q8 + 292398q7 + 1384190q6 − 780377q5 + 92840q4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 172070q3 + 82650q2 − 16625q + 1250)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β4 = −1728q3(236868899q15 − 167106540q14 − 27475861q13 + 30085783q12  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 71194720q11 − 93267345q10 + 26586077q9 − 34251559q8 + 17589658q7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 3235715q6 − 1579579q5 + 967928q4 + 321965q3 − 16556q2 + 5065q + 100)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β3 = +10368q6(68241566q12 − 18895570q11 − 20786934q10 + 7199369q9  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='+ 33561740q8 − 22673859q7 + 12236878q6 − 12682141q5 + 3702336q4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 429295q3 − 709332q2 + 75072q − 25990)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β2 = −62208q9(13326500q9 + 1552000q8 − 5598873q7 − 169064q6 + 7716992q5  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='− 2044760q4 + 2513825q3 − 1187532q2 + 408704q + 15928)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β1 = +8211456q12(71676q6 + 32140q5 − 37217q4 − 23402q3 + 31535q2 − 268q + 4268)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='β0 = −8671297536q15(q − 1)(22q2 + 37q + 22)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='This expression is very long,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' but we should remember that it captures all the higher spin  charges of all five physical states at level 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='2  Yangian limit  The q-expansion of the physical solutions around q = 0 is as follows:  �  �  �  �  �  �  �  −10 − 24  13q + O(q2)  −5 − 264  65 q2 + O(q3)  − 528  25 q3 + 2376  1625q4 + O(q5)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3)  �  �  �  �  �  �  �  −5 − 22  7 q − +O(q2)  132  5 q3 + 6138  25 q4 + O(q5)  2 − 90  7 q + O(q2)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='4)  �  �  �  �  �  �  �  −5 − 39  14q + O(q2)  66  5 q3 − 136176  2275 q4 + O(q5)  3 + 165  26 q + O(q2)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='5)  �  �  �  �  �  �  �  −12q3 − 1410  7 q4 + O(q5)  2 + 30  7 q + O(q2)  3 − 30q + O(q2)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='6)  – 100 –  �  �  �  �  �  �  �  −6q3 + 45q4 + O(q5)  2 − 20q2 + O(q3)  4 + 10q + O(q2)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='7)  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='3  Local limit q → 1  On the other hand, the expansion around the local point is more interesting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' The five  solutions have expansion around q = 1 as follows:  �  �  �  �  �  �  �  0 − 88  81(1 − q) + 1496  6561(1 − q)2 + O((1 − q)3)  3 − 148  81 (1 − q) − 74  81(1 − q)2 + O((1 − q)3)  6 − 88  81(1 − q) − 8624  6561(1 − q)2 + O((1 − q)3)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='8)  �  �  �  �  �  �  �  −  6  1−q + 6 − 10  3 (1 − q) − 5  3(1 − q)2 + O((1 − q)3)  6+  √  14  2  − 11  12(1 − q) − 11(168+5  √  14)  4032  (1 − q)2 + O((1 − q)3)  6−  √  14  2  − 11  12(1 − q) − 11(168−5  √  14)  4032  (1 − q)2 + O((1 − q)3)  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='9)  �  �  �  �  �  �  �  −  6  1−q − 2  2  3 5  1  3 (1 − q)− 1  3 + 6 + O((1 − q)  1  3 )  −  6  1−q − 2  2  3 5  1  3 e− 2πi  3 (1 − q)− 1  3 + 6 + O((1 − q)  1  3 )  −  6  1−q − 2  2  3 5  1  3 e  2πi  3 (1 − q)− 1  3 + 6 + O((1 − q)  1  3 )  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='10)  �  �  �  �  �  �  �  −  6  1−q + 3 × 5  1  4 (1 − q)− 1  2 − 19  √  5  18  + O((1 − q)  1  2 )  −  6  1−q − 3 × 5  1  4 (1 − q)− 1  2 − 19  √  5  18  + O((1 − q)  1  2 )  −  6  1−q − 2(4  √  5−27)  9  + O((1 − q))  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='11)  �  �  �  �  �  �  �  −  6  1−q + 3i × 5  1  4 (1 − q)− 1  2 + 19  √  5  18  + O((1 − q)  1  2 )  −  6  1−q − 3i × 5  1  4 (1 − q)− 1  2 + 19  √  5  18  + O((1 − q)  1  2 )  −  6  1−q + 2(4  √  5+27)  9  + O((1 − q))  (F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='12)  References  [1] A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Zamolodchikov, Higher Order Integrals of Motion in Two-Dimensional Models of the  Field Theory with a Broken Conformal Symmetry, JETP Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' 46 (1987) 160–164.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' Pure  Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Bazhanov, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Zamolodchikov, Integrable quantum field theories  in finite volume: Excited state energies, Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Zamolodchikov, Integrals of Motion and S Matrix of the (Scaled) T=T(c) Ising Model  with Magnetic Field, Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' Mod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' Stud.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Pure Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content='-K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Yang, Deformations of Conformal Field Theories and Soliton Equations,  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Bazhanov, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Lukyanov, and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Zamolodchikov, Integrable structure of conformal  field theory, quantum KdV theory and thermodynamic Bethe ansatz, Commun.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  177 (1996) 381–398, [hep-th/9412229].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
+page_content='  [9] A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/OtE4T4oBgHgl3EQfkA1f/content/2301.05147v1.pdf'}
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+1 
+ 
+URSI RCRS 2022, IIT (Indore), India, 1 –4 December, 2022 
+ 
+ 
+VIPER:A Plasma Wave Detection Instrument onboard Indian Venus Orbiter Spacecraft 
+ 
+Vipin K. Yadav 
+Space Physics Laboratory (SPL), Vikram Sarabhai Space Centre (VSSC), Indian Space Research Organization (ISRO), 
+Thiruvananthapuram 695022, Kerala, India 
+ 
+Abstract 
+Plasma waves are observed in almost all the solar system 
+objects 
+- 
+planets, 
+their 
+satellites, 
+comets, 
+Sun, 
+interplanetary medium, etc. The planetary ionospheres are 
+capable of sustaining plasma waves which are observed 
+there and play an important role in the ionospheric 
+dynamics by propagating energy across different space 
+regions and provide acceleration to particles to attain high 
+energies for transportation. The study of planetary plasma 
+waves also provides information on the solar wind – 
+planet interaction, the energy distribution in the 
+ionospheric plasma of that planet, etc. 
+Venus does not possess a global magnetic field unlike 
+Earth. Thesolar EUV radiation ionizes the neutrals and 
+generates a plasma environment around Venus which can 
+sustain plasma waves. Very few attempts are made to 
+observe all plasma waves that can exist around Venus and 
+that too with instruments having a limited dynamic range 
+such as with PVO (Pioneer Venus Orbiter) and Venus 
+Express. However, there are some other plasma waves 
+which can exist around Venus but are yet to be observed.  
+ISRO is planning to send an orbiter mission to Venus in 
+near future where a suit of instruments named VIPER 
+(Venus Ionospheric Plasma wavE detectoR) is onboard to 
+observe Venusian plasma waves. The plasma wave 
+observations around Venus and VIPER onboard ISRO‟s 
+Venus Orbiter Spacecraft are discussed in this paper. 
+1. Introduction 
+Venus is a terrestrial planet which does not possess a 
+global magnetic field. Thesolar radiation (dominantly 
+EUV) interacts with the dense Venus atmosphere and 
+ionizes large number of neutral atoms and molecules and 
+the ionosphere gets generated. The magnetic field 
+observed around Venus is a result from the solar wind 
+interaction with the upper atmosphere of the Venus. The 
+induced magnetic field of Venus varies ~ 50 to 150 nT. 
+The first plasma wave detection around Venus was 
+carried out by PVO in 1978 with a suit of instruments 
+such as magnetometer [1, 2], electric dipole [3] and 
+electron temperature probe, [4].  
+The electric dipole had an effective length of 0.75 m 
+formed by a pair of electric field sensors having wire 
+circles of diameter 10.5 cm. The electric field sensor had 
+four frequency channels: 100 Hz, 730 Hz, 5.4 kHz and 30 
+kHz. The automatic gain control amplifiers had a rise time 
+of 50 ms and a decay time of about 500 ms. The Orbiter 
+Electron Temperature Probe (OETP) was designed to 
+measure the plasma parameters in Venus ionosphere - 
+electron (ne) and ion (ni) plasma density, electron plasma 
+temperature (Te) and the spacecraft potential (Vsc). It 
+consisted of two cylindrical sensors – one placed radially 
+at the end of a 1 m long boom and the other placed axially 
+at a distance of 0.4 m away from the spacecraft with a 
+common electronics unit [4]. The Venus Express in 2005 
+from ESA also carried two triaxial magnetometer sensors 
+to measure the magnetic field in the Venus ionosphere 
+with one sensor mounted directly on the spacecraft and 
+the other at the end of a 1 m boom. The magnetometer 
+sensors have a dynamic range from ± 32.8 to ± 8388.6 nT 
+with 128 Hz cadence [5]. Table 1 lists different plasma 
+wave detection instruments which have flown onboard 
+various missions to Venus for measurements. 
+Table 1 
+Mission 
+Year 
+Agency/ 
+Country 
+Plasma wave 
+Instrument 
+Other 
+Plasma 
+Instruments 
+Mariner-
+10  
+1974 
+NASA 
+Magnetometer 
+Plasma Ion 
+Probe 
+Pioneer 
+Venus 
+Orbiter 
+(PVO)  
+1978 
+NASA 
+Orbiter 
+Electric Field 
+Detector 
+(OEFD), 
+Magnetometer 
+(OMAG), 
+Orbiter 
+Electron 
+Temperature 
+Probe (OETP) 
+Orbiter Ion 
+Mass 
+Spectrometer 
+(OIMS), 
+Orbiter 
+Plasma 
+Analyzer 
+(OPA), 
+Orbiter 
+Retarding 
+Potential 
+Analyzer 
+(ORPA), 
+Orbiter Radio 
+Occultation  
+Venera 
+11/12  
+1978 
+USSR 
+Magnetometer 
+---- 
+Venus 
+Express  
+2005 
+ESA 
+Magnetometer 
+ASPERA-4 
+PVO measured the electron plasma density varies from a 
+maximum of 5 × 105 cm-3 at 150 km to about 104 cm-3 at 
+900 km whereas the electron temperature has a variation 
+between 1100o K at 150 km to 8000o K at about 900 km. 
+The ion temperature is less than electron temperature at 
+the same altitude at 500o K at 150 km to 1300o K at 900 
+
+U.
+R2 
+ 
+km. The typical plasma and magnetic field parameters 
+around Venus [6, 7] are summarized in Table 2. 
+Table 2 
+Plasma parameter 
+Range 
+Electron number density, ne (cm-3) 
+3 × 102 – 5 × 
+105 
+Electron temperature, Te (eV) 
+0.1 – 1.7 
+Ion number density, ni (cm-3) 
+10 – 2 × 105 
+Ion temperature, Ti (eV) 
+0.02 – 0.3 
+Background magnetic field, B (nT) 
+50 – 165 
+2. Venus Plasma Wave Observations 
+PVO was the first best equipped spacecraft to observe 
+plasma waves near the Venus. Its electric field sensors 
+observed a strong and highly variable solar wind 
+interaction with the Venusian ionosphere. PVO observed 
+electromagnetic whistler waves in 100 Hz, lower hybrid 
+waves in 30 kHz range [8] and electron plasma 
+oscillations in 20-54 kHz frequency range [9]. Galileo 
+during its flyby of Venus observed electrostatic Langmuir 
+waves [10]. Venus Express detected proton cyclotron 
+waves in Venus ionosphere with a set of fluxgate 
+magnetometers onboard [11, 12]. Mirror mode waves 
+were also observed in the induced magnetosphere of 
+Venus by Venus Express [13, 14]. Apart from the above 
+mentioned waves, ion acoustic waves (IAW) with 
+frequency fIAW ≈ 100 Hz are proposed to be present in the 
+Venus ionosphere as a consequence of the ion acoustic 
+beam instability due to O+ ions [15]. Magnetosonic waves 
+having frequencies between 40-50 mHz (in the spacecraft 
+frame) are observed by Venus Express [16]. A review on 
+plasma waves around Venus is given elsewhere [17]. A 
+summary of various plasma wave observed in the 
+ionosphere of Venus is given in Table 3. 
+Table 3 
+Observed 
+Plasma 
+Waves 
+Spacecraft 
+Instruments 
+Frequency  
+Electron 
+plasma 
+oscillations 
+PVO, 
+Galileo 
+OEFD, 
+MAG 
+≈ 50 kHz 
+IAW 
+PVO 
+OEFD, 
+OMAG, 
+OETP 
+730 Hz, 
+5.4 kHz 
+ Whistler 
+waves,  
+ = < 100 
+Hz 
+Lower hybrid 
+waves 
+30 kHz 
+Langmuir 
+waves  
+Galileo 
+PWS, MAG 
+200 Hz - 7 
+kHz 
+Proton 
+cyclotron 
+waves 
+Venus 
+Express 
+MAG 
+= < 0.5 Hz 
+Mirror mode 
+waves 
+30 – 300 
+mHz 
+Magnetosonic 
+waves 
+40 – 50 
+mHz, < 
+100 mHz 
+Table 4 lists all the plasma waves that are expected to be 
+present around Venus and are to be observed by VIPER. 
+Table 4 
+Plasma Waves/oscillations  Expected frequency 
+Hydromagnetic waves 
+40 – 50 mHz, < 100 
+mHz 
+Mirror mode waves 
+30 – 300 mHz 
+Proton cyclotron waves 
+= < 0.5 Hz 
+Whistler waves 
+= < 100 Hz 
+Ion cyclotron waves 
+19 – 625 Hz 
+Mix-mode waves 
+50 – 1000 Hz 
+Electron cyclotron waves 
+1.4 – 4.5 kHz   
+Ion acoustic waves 
+730 Hz, 5.4 kHz 
+Langmuir waves 
+200 Hz - 7 kHz 
+Lower hybrid waves 
+30 kHz 
+Electron plasma oscillations 
+≈ 50 kHz 
+Table 5 list the plasma waves that can exist around Venus 
+but are yet to be observed. 
+Table 5 
+Un-observed 
+Plasma Waves 
+Expected 
+frequency 
+Importance 
+Electron 
+cyclotron waves 
+1.4 – 4.5 
+kHz 
+Electron 
+transport 
+from Venus 
+Ion cyclotron 
+waves 
+19 – 625 
+Hz 
+Particle loss from 
+the 
+Venusian 
+ionosphere 
+Mix-mode 
+waves 
+50 – 1000 
+Hz 
+Venus 
+ionospheric 
+heating 
+A hand-made schematic distribution of plasma waves 
+around Venus is shown in Figure 1. 
+ 
+Figure 1.The distribution of plasma waves around Venus 
+(Not to scale in altitude). 
+It is to be noted that there are only couple of attempts 
+made to observe all plasma waves that can exist in the 
+Venus ionosphere and that too with instruments having a 
+limited dynamic range. However, the limited instrumental 
+capability onboard PVO and Venus Express shows that a 
+number of plasma waves exist in the ionosphere of Venus. 
+There are some plasma waves which may exist in the 
+ionosphere of Venus but are not detected such electron 
+and ion cyclotron waves, mix-mode waves, etc. Although 
+
+Magnetosheath
+Pickupions
+n
+Boundary/Layer
+loncyclotranwave
+(Proton)
+ECW
+Photoelectronutflow
+ESW
+(Whistler)
+EMwaves fromlighthing
+MA
+M
+EPO
+Solar
+e
+Hotplasasheet
+Radiation
+M
+IAW
+Magnetotail
+Solar
+M-mW
+Magnetosonic
+Wind
+Waves
+IMF
+MA
+x
+Coldplasmaskeet
+Reconnection
+LW
+LHW
+M-mW:Mix-modeWaves
+LHW:LowerHybridWaves
+ICW
+EcW:ElectroncyciotronWaves
+LW:Langmcir Waves
+AW:lonAcousticWaves
+Interplanetaryshocks(IPS)
+1
+IcW:loncyclotron Waves
+EPo:ElectronPlasmaOscillations3 
+ 
+Langmuir, ion acoustic, whistler and proton cyclotron 
+waves are detected by earlier Venus missions, it shall be 
+prudent to make an attempt again to observe these plasma 
+waves if the dynamic range of the measuring instrument 
+makes it possible so as to verify the earlier measurements 
+and to get some additional scientific information if 
+possible.Electron plasma frequency (fpe) & subsequently 
+electron plasma (Langmuir) wave frequency (fEPW) can be 
+computed as follows: (ne ≈ 103 - 5 × 105 cm-3, fpe (min.) = 
+0.284 MHz; fpe (max.) = 6.35 MHz. 
+3. VIPER: Science Objectives 
+The proposed scientific instruments, in the form of a suit 
+(VIPER) are – a customized Langmuir probe (LP) to 
+measure the electron & ion number density and electron 
+plasma temperature, a triaxial electric field sensor (EFS) 
+to measure the oscillating plasma wave electric field, a 
+triaxial search-coil magnetometer (SCM) to measure the 
+oscillating plasma wave magnetic field around Venus and 
+a triaxial fluxgate magnetometer (FGM) to measure the 
+background magneticfield around Venus. All these 
+sensors shall be mounted on two separate booms thereby 
+keeping them away from the spacecraft to avoid the 
+sheath and shielding effects. 
+The scientific objectives of VIPER are: 
+(i) To study the plasma phenomena around Venus by 
+exploring it in the prevailing localized regions. For 
+this purpose, the electron and ion plasma parameters 
+are going to be measured in-situ with LP onboard the 
+orbiter spacecraft around Venus.  
+(ii) To study of the interplanetary and induced magnetic 
+field structure around Venus. For this purpose, the 
+background 
+magnetic 
+field 
+is 
+going 
+to 
+be 
+continuously measured in-situ with FGM onboard the 
+orbiter spacecraft around Venus. 
+(iii)  To detect and observe the plasma waves around 
+Venus and to explore their role in modulating the 
+plasma dynamics around Venus. For this purpose, the 
+plasma wave frequency is going to be measured with 
+EFS and SCM.   
+Table 6 lists the scientific objectives pertaining to the 
+measurement parameters and sampling requirements. 
+Table 6 
+Science Objectives 
+Measurement parameters 
+To explore the plasma 
+environment 
+around 
+Venus and to study the 
+plasma 
+phenomena 
+prevailing in localized 
+regions. 
+Continuous measurement of 
+plasma parameters such as 
+electron and ion number 
+density, electron and ion 
+plasma temperature around 
+the Venus. 
+Study 
+of 
+the 
+interplanetary 
+and 
+induced magnetic field 
+structure 
+prevailing 
+around Venus. 
+Continuous measurement of 
+background magnetic field 
+around the Venus. 
+Characterization 
+of 
+Venusian plasma waves 
+and 
+their 
+role 
+in 
+Continuous detection and 
+measurement of the plasma 
+wave electric and magnetic 
+modulating the plasma 
+dynamics around Venus.  
+fields 
+along 
+with 
+the 
+localized plasma parameters 
+around the Venus. 
+Study 
+of 
+various 
+physical 
+phenomena 
+taking 
+place 
+around 
+Venus 
+such 
+as 
+the 
+plasma 
+energy 
+distribution, 
+plasma 
+heating, 
+particle 
+acceleration and their 
+escape.  
+Continuous measurements of 
+plasma wave parameters and 
+charge particle distribution 
+measurements along with 
+their number densities and 
+energies around the Venus. 
+Data from VIPER and other 
+onboard instruments to be 
+used.  
+4. VIPER Plasma Wave Detection 
+The identification of plasma waves by VIPER is done 
+after detecting the time varying (oscillating) electric field 
+and magnetic field signals. Initially the plasma parameters 
+such as electron and ion number density and electron and 
+ion plasma temperature shall be estimated using the LP 
+along with the background steady state which is going to 
+be measured by the FGM as given in Table 7. 
+Table 7 
+Instrument / 
+Scientific Aim 
+Plasma/Field 
+Parameter & 
+Range 
+Measurements 
+Required 
+Langmuir 
+Probe (LP) 
+Plasma 
+parameter 
+measurements 
+ne; [102 - 106 cm-3] 
+Te; [0.1 - 1 eV] 
+ni (bulk); [102 - 105 
+cm-3] 
+Ti (bulk); [0.06 – 
+0.4 eV] 
+Electron & Ion 
+saturation 
+currents, 
+Complete I-V 
+characteristics 
+Electric Field 
+Sensor (EFS) 
+Oscillating 
+plasma wave 
+electric field 
+ω (ES & EM) [1 
+Hz - 55 kHz]; 
+E1 ; [mV/m] 
+Wave electric 
+field at different 
+frequencies. 
+Fluxgate 
+Magnetometer 
+(FGM) 
+Background 
+magnetic field 
+measurements 
+B0 ; [1 – 300 nT] 
+Bx1, By1, Bz1 and 
+Bx2, By2, Bz2 
+Search-coil 
+Magnetometer 
+(SCM) 
+Oscillating 
+plasma wave 
+magnetic field 
+ω (EM only) ; [1 
+Hz – 55 kHz] 
+B1 ; [1 – 300 nT] 
+Wave magnetic 
+field at different 
+frequencies. 
+Here, ω is the angular frequency (= 2πf) of the wave 
+having frequency f, E1 and B1 are the time-varying wave 
+electric and magnetic fields respectively. These plasma 
+and field parameters are to be used to estimate the plasma 
+characteristic frequencies such as the electron/ion plasma 
+frequency, 
+electron/ion 
+cyclotron 
+frequency 
+and 
+secondary plasma parameters as given in Table 8. 
+Table 8 
+Plasma Parameters 
+Measured 
+quantities / 
+constants 
+Value 
+
+4 
+ 
+Electron cyclotron 
+frequency,  
+ωc = 2π (e B0) / me 
+B0 , e , me 
+2.8 × 106 B0 
+Hz 
+Ion cyclotron 
+frequency, 
+Ωc = 2π (Z e B0) / mi 
+B0 , mi , mp , Z 
+μ = mi /mp 
+1.52 × 103 Z 
+μ-1 B0 Hz 
+Electron plasma 
+frequency, 
+ωpe = 2π (e2 ne / me 
+ε0)1/2 
+ne , e , me ,ε0 
+8.98 × 103 
+ne
+1/2 Hz 
+Ion plasma 
+frequency, 
+ωpi = 2π (Z2 e2 ni / mi 
+ε0)1/2 
+Z , e , ni , mi , 
+ε0 
+2.1 × 102 Z 
+μ-1/2 ni
+1/2 Hz 
+Electron thermal 
+velocity, 
+vthe = (KBTe / me)1/2 
+KB, Te , me 
+4.19 × 105 Te 
+m/sec 
+Ion sound velocity, 
+vs = (γ Z KBTe / 
+mi)1/2 
+k , Te , mi , Z , 
+γ , μ 
+μ = mi /mp , γ = 
+cp/cv 
+9.79 × 103 (γ 
+Z Te /μ)1/2 
+m/sec 
+Ion thermal velocity, 
+vthi = (k Ti / mi)1/2 
+KB, Ti , me 
+9.79 × 103 
+Ti
+1/2 μ-1/2 
+m/sec 
+Debye length,  
+λD = (KBTe / e2 ne)1/2 
+KB, Te , ne , e 
+7.43 Te
+1/2 ne
+-
+1/2 m 
+Alfven velocity 
+vA = B0 / (µ0ρ)1/2 
+B0 ,µ0 ,ρ, μ 
+ρ = nimi ,μ = 
+mi /mp  
+2.18×109 μ-
+1/2 ni
+-1/2 B0 
+m/sec 
+Here, B0 is the background magnetic field, e is electronic 
+charge, me is electron mass, Z is the atomic number, mi is 
+ion mass, mp is proton mass, c is velocity of light in free 
+space, ε0 is the permittivity of the free space, KB is the 
+Boltzmann constant, Te is the electron temperature, γ is 
+the ratio of specific heats, µ0 is the permeability of the free 
+space, ρ is the ion mass density, ni is ion number density. 
+The estimated plasma parameters and measured magnetic 
+field along with the frequency of the oscillating electric 
+and magnetic field shall be fitted in the dispersion 
+relations of various plasma waves that can exist around 
+the Venus and the outcome shall be analysed for proper 
+identification. For example, the dispersion relation of an 
+electron plasma (or Langmuir) wave is ω2 = ωp
+2 + (3/2) 
+k2vth
+2. Here, the variables are ω (measured from EFS), ωpe 
+(estimated from ne measured by LP), vthe (estimated from 
+Te measured by LP) and k. For a given small range of k, 
+the dispersion relation shall be satisfied and the existence 
+of the wave shall be established. 
+5. References 
+1. C.T. Russell, et al., “On the search for an intrinsic 
+magnetic field at Venus”, Proc. 11th Lunar Planetary 
+Science Conference, 1980, pp. 1897-1906  
+2. C.T. Russell, et al., “Pioneer Venus orbiter fluxgate 
+magnetometer”, IEEE Transactions on Geoscience and 
+Remote Sensing, GE-18, 1, 1980, pp. 32-35, doi:10.1109/ 
+TGRS.1980.350256 
+3. Scarf, et al., “The Pioneer Venus Orbiter Plasma Wave 
+Investigation”, IEEE Transactions on Geoscience and 
+Remote Sensing, GE-18, 1, 1980, pp. 36-38, doi:10.1109/ 
+TGRS.1980.350257 
+4. J.P. Krehbiel, et al., “Pioneer Venus Orbiter Electron 
+Temperature Probe”, IEEE Trans. on Geoscience and 
+Remote Sensing, GE-18, 1, 1980, pp. 49-54, doi:10.1109/ 
+TGRS.1980.350260 
+5. T.L. Zhang, et al., “Magnetic field investigation of the 
+Venus plasma environment: Expected new results from 
+Venus Express”, Planetary Space Science, 54, 2006, pp. 
+1336-1343, doi:10.1016/j.pss.2006.04.018 
+6. J.G. Luhmann, et al., “Characteristics of the Mars-like 
+limit of the Venus-Solar wind Interaction”, Journal of 
+Geophysical Research, 92, A8, 1987, pp. 8545-8557, doi: 
+10.1029/JA092iA08p08545 
+7. S.J. Bauer, et al., “The Venus Ionosphere”, Advances in 
+Space 
+Research, 
+5, 
+11, 
+1985, 
+pp. 
+233-267, 
+doi:10.1016/0273-1177(85)90203-0 
+8. F.L. Scarf, et al., “Plasma Waves Near Venus: Initial 
+Observations”, 
+Science, 
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+1979, 
+pp. 
+748-750, 
+doi:10.1126/science.203.4382.748 
+9. G.K. Crawford, R.J. Strangeway, and C.T. Russell, 
+“Electron Plasma Oscillations in the Venus Foreshock”, 
+Geophysical Research Letters, 17, 11, 1990, pp. 1805-
+1808, doi:10.1029/GL017i011p01805 
+10. G.B. Hospodarsky, et al., “Fine structure of Langmuir 
+waves observed upstream of the bow shock at Venus”, 
+Journal of Geophysical Research, 99, A7, 1994,pp. 
+13,363-13,371, doi: 10.1029/94JA00868 
+11. M. Delva, et al., “First upstream proton cyclotron 
+wave observations at Venus”, Geophysical Research 
+Letters, 35, 2008, L03105, doi:10.1029/2007GL032594 
+12. M. Delva, et al., “Proton cyclotron waves in the solar 
+wind at Venus”, Journal of Geophysical Research, 113, 
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+mode waves in Venus‟ magnetosheath?”, Geophysical 
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+18. F.F. Chen, “Introduction to Plasma Physics and 
+Controlled Fusion”, Third Edition, Chapter 4 “Waves in 
+Plasma”, Section 4.6 „Ion Waves‟, 1984, pp. 91 
+
diff --git a/QNE1T4oBgHgl3EQfagS4/content/tmp_files/load_file.txt b/QNE1T4oBgHgl3EQfagS4/content/tmp_files/load_file.txt
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@@ -0,0 +1,295 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf,len=294
+page_content='1  URSI RCRS 2022, IIT (Indore), India, 1 –4 December, 2022  VIPER:A Plasma Wave Detection Instrument onboard Indian Venus Orbiter Spacecraft  Vipin K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Yadav  Space Physics Laboratory (SPL), Vikram Sarabhai Space Centre (VSSC), Indian Space Research Organization (ISRO),  Thiruvananthapuram 695022, Kerala, India  Abstract  Plasma waves are observed in almost all the solar system  objects planets,  their  satellites,  comets,  Sun,  interplanetary medium, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The planetary ionospheres are  capable of sustaining plasma waves which are observed  there and play an important role in the ionospheric  dynamics by propagating energy across different space  regions and provide acceleration to particles to attain high  energies for transportation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The study of planetary plasma  waves also provides information on the solar wind –  planet interaction, the energy distribution in the  ionospheric plasma of that planet, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Venus does not possess a global magnetic field unlike  Earth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Thesolar EUV radiation ionizes the neutrals and  generates a plasma environment around Venus which can  sustain plasma waves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Very few attempts are made to  observe all plasma waves that can exist around Venus and  that too with instruments having a limited dynamic range  such as with PVO (Pioneer Venus Orbiter) and Venus  Express.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' However, there are some other plasma waves  which can exist around Venus but are yet to be observed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  ISRO is planning to send an orbiter mission to Venus in  near future where a suit of instruments named VIPER  (Venus Ionospheric Plasma wavE detectoR) is onboard to  observe Venusian plasma waves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The plasma wave  observations around Venus and VIPER onboard ISRO‟s  Venus Orbiter Spacecraft are discussed in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Introduction  Venus is a terrestrial planet which does not possess a  global magnetic field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Thesolar radiation (dominantly  EUV) interacts with the dense Venus atmosphere and  ionizes large number of neutral atoms and molecules and  the ionosphere gets generated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The magnetic field  observed around Venus is a result from the solar wind  interaction with the upper atmosphere of the Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The  induced magnetic field of Venus varies ~ 50 to 150 nT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  The first plasma wave detection around Venus was  carried out by PVO in 1978 with a suit of instruments  such as magnetometer [1, 2], electric dipole [3] and  electron temperature probe, [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  The electric dipole had an effective length of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='75 m  formed by a pair of electric field sensors having wire  circles of diameter 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='5 cm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The electric field sensor had  four frequency channels: 100 Hz, 730 Hz, 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 kHz and 30  kHz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The automatic gain control amplifiers had a rise time  of 50 ms and a decay time of about 500 ms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The Orbiter  Electron Temperature Probe (OETP) was designed to  measure the plasma parameters in Venus ionosphere -  electron (ne) and ion (ni) plasma density, electron plasma  temperature (Te) and the spacecraft potential (Vsc).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' It  consisted of two cylindrical sensors – one placed radially  at the end of a 1 m long boom and the other placed axially  at a distance of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 m away from the spacecraft with a  common electronics unit [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The Venus Express in 2005  from ESA also carried two triaxial magnetometer sensors  to measure the magnetic field in the Venus ionosphere  with one sensor mounted directly on the spacecraft and  the other at the end of a 1 m boom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The magnetometer  sensors have a dynamic range from ± 32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='8 to ± 8388.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='6 nT  with 128 Hz cadence [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Table 1 lists different plasma  wave detection instruments which have flown onboard  various missions to Venus for measurements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 1  Mission  Year  Agency/  Country  Plasma wave  Instrument  Other  Plasma  Instruments  Mariner-  10  1974  NASA  Magnetometer  Plasma Ion  Probe  Pioneer  Venus  Orbiter  (PVO)  1978  NASA  Orbiter  Electric Field  Detector  (OEFD),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Magnetometer  (OMAG),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Orbiter  Electron  Temperature  Probe (OETP)  Orbiter Ion  Mass  Spectrometer  (OIMS),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Orbiter  Plasma  Analyzer  (OPA),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Orbiter  Retarding  Potential  Analyzer  (ORPA),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Orbiter Radio  Occultation  Venera  11/12  1978  USSR  Magnetometer  ----  Venus  Express  2005  ESA  Magnetometer  ASPERA-4  PVO measured the electron plasma density varies from a  maximum of 5 × 105 cm-3 at 150 km to about 104 cm-3 at  900 km whereas the electron temperature has a variation  between 1100o K at 150 km to 8000o K at about 900 km.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  The ion temperature is less than electron temperature at  the same altitude at 500o K at 150 km to 1300o K at 900  U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  R2  km.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' The typical plasma and magnetic field parameters  around Venus [6, 7] are summarized in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 2  Plasma parameter  Range  Electron number density, ne (cm-3)  3 × 102 – 5 ×  105  Electron temperature, Te (eV)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='1 – 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='7  Ion number density, ni (cm-3)  10 – 2 × 105  Ion temperature, Ti (eV)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='02 – 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='3  Background magnetic field, B (nT)  50 – 165  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Venus Plasma Wave Observations  PVO was the first best equipped spacecraft to observe  plasma waves near the Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Its electric field sensors  observed a strong and highly variable solar wind  interaction with the Venusian ionosphere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' PVO observed  electromagnetic whistler waves in 100 Hz, lower hybrid  waves in 30 kHz range [8] and electron plasma  oscillations in 20-54 kHz frequency range [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Galileo  during its flyby of Venus observed electrostatic Langmuir  waves [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Venus Express detected proton cyclotron  waves in Venus ionosphere with a set of fluxgate  magnetometers onboard [11, 12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Mirror mode waves  were also observed in the induced magnetosphere of  Venus by Venus Express [13, 14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Apart from the above  mentioned waves, ion acoustic waves (IAW) with  frequency fIAW ≈ 100 Hz are proposed to be present in the  Venus ionosphere as a consequence of the ion acoustic  beam instability due to O+ ions [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Magnetosonic waves  having frequencies between 40-50 mHz (in the spacecraft  frame) are observed by Venus Express [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' A review on  plasma waves around Venus is given elsewhere [17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' A  summary of various plasma wave observed in the  ionosphere of Venus is given in Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 3  Observed  Plasma  Waves  Spacecraft  Instruments  Frequency  Electron  plasma  oscillations  PVO,  Galileo  OEFD,  MAG  ≈ 50 kHz  IAW  PVO  OEFD,  OMAG,  OETP  730 Hz,  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 kHz  Whistler  waves,  = < 100  Hz  Lower hybrid  waves  30 kHz  Langmuir  waves  Galileo  PWS, MAG  200 Hz - 7  kHz  Proton  cyclotron  waves  Venus  Express  MAG  = < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='5 Hz  Mirror mode  waves  30 – 300  mHz  Magnetosonic  waves  40 – 50  mHz, <  100 mHz  Table 4 lists all the plasma waves that are expected to be  present around Venus and are to be observed by VIPER.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 4  Plasma Waves/oscillations  Expected frequency  Hydromagnetic waves  40 – 50 mHz, < 100  mHz  Mirror mode waves  30 – 300 mHz  Proton cyclotron waves  = < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='5 Hz  Whistler waves  = < 100 Hz  Ion cyclotron waves  19 – 625 Hz  Mix-mode waves  50 – 1000 Hz  Electron cyclotron waves  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 – 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='5 kHz  Ion acoustic waves  730 Hz, 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 kHz  Langmuir waves  200 Hz - 7 kHz  Lower hybrid waves  30 kHz  Electron plasma oscillations  ≈ 50 kHz  Table 5 list the plasma waves that can exist around Venus  but are yet to be observed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 5  Un-observed  Plasma Waves  Expected  frequency  Importance  Electron  cyclotron waves  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 – 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='5  kHz  Electron  transport  from Venus  Ion cyclotron  waves  19 – 625  Hz  Particle loss from  the  Venusian  ionosphere  Mix-mode  waves  50 – 1000  Hz  Venus  ionospheric  heating  A hand-made schematic distribution of plasma waves  around Venus is shown in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='The distribution of plasma waves around Venus  (Not to scale in altitude).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  It is to be noted that there are only couple of attempts  made to observe all plasma waves that can exist in the  Venus ionosphere and that too with instruments having a  limited dynamic range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' However, the limited instrumental  capability onboard PVO and Venus Express shows that a  number of plasma waves exist in the ionosphere of Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  There are some plasma waves which may exist in the  ionosphere of Venus but are not detected such electron  and ion cyclotron waves, mix-mode waves, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Although  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Magnetosheath  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Pickupions  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='n  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Boundary/Layer  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='loncyclotranwave  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='(Proton)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='ECW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Photoelectronutflow  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='ESW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='(Whistler)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='EMwaves fromlighthing  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='MA  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='M  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='EPO  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Solar  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='e  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Hotplasasheet  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Radiation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='M  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='IAW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Magnetotail  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Solar  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='M-mW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Magnetosonic  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Wind  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Waves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='IMF  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='MA  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='x  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Coldplasmaskeet  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Reconnection  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='LW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='LHW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='M-mW:Mix-modeWaves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='LHW:LowerHybridWaves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='ICW  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='EcW:ElectroncyciotronWaves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='LW:Langmcir Waves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='AW:lonAcousticWaves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Interplanetaryshocks(IPS)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='IcW:loncyclotron Waves  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='EPo:ElectronPlasmaOscillations3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Langmuir,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' ion acoustic,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' whistler and proton cyclotron  waves are detected by earlier Venus missions,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' it shall be  prudent to make an attempt again to observe these plasma  waves if the dynamic range of the measuring instrument  makes it possible so as to verify the earlier measurements  and to get some additional scientific information if  possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='Electron plasma frequency (fpe) & subsequently  electron plasma (Langmuir) wave frequency (fEPW) can be  computed as follows: (ne ≈ 103 - 5 × 105 cm-3, fpe (min.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=') =  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='284 MHz;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' fpe (max.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=') = 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='35 MHz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' VIPER: Science Objectives  The proposed scientific instruments,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' in the form of a suit  (VIPER) are – a customized Langmuir probe (LP) to  measure the electron & ion number density and electron  plasma temperature,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' a triaxial electric field sensor (EFS)  to measure the oscillating plasma wave electric field,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' a  triaxial search-coil magnetometer (SCM) to measure the  oscillating plasma wave magnetic field around Venus and  a triaxial fluxgate magnetometer (FGM) to measure the  background magneticfield around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' All these  sensors shall be mounted on two separate booms thereby  keeping them away from the spacecraft to avoid the  sheath and shielding effects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  The scientific objectives of VIPER are:  (i) To study the plasma phenomena around Venus by  exploring it in the prevailing localized regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' For  this purpose, the electron and ion plasma parameters  are going to be measured in-situ with LP onboard the  orbiter spacecraft around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  (ii) To study of the interplanetary and induced magnetic  field structure around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' For this purpose, the  background  magnetic  field  is  going  to  be  continuously measured in-situ with FGM onboard the  orbiter spacecraft around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  (iii)  To detect and observe the plasma waves around  Venus and to explore their role in modulating the  plasma dynamics around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' For this purpose, the  plasma wave frequency is going to be measured with  EFS and SCM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 6 lists the scientific objectives pertaining to the  measurement parameters and sampling requirements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 6  Science Objectives  Measurement parameters  To explore the plasma  environment  around  Venus and to study the  plasma  phenomena  prevailing in localized  regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Continuous measurement of  plasma parameters such as  electron and ion number  density, electron and ion  plasma temperature around  the Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Study  of  the  interplanetary  and  induced magnetic field  structure  prevailing  around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Continuous measurement of  background magnetic field  around the Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Characterization  of  Venusian plasma waves  and  their  role  in  Continuous detection and  measurement of the plasma  wave electric and magnetic  modulating the plasma  dynamics around Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  fields  along  with  the  localized plasma parameters  around the Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Study  of  various  physical  phenomena  taking  place  around  Venus  such  as  the  plasma  energy  distribution,  plasma  heating,  particle  acceleration and their  escape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Continuous measurements of  plasma wave parameters and  charge particle distribution  measurements along with  their number densities and  energies around the Venus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Data from VIPER and other  onboard instruments to be  used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' VIPER Plasma Wave Detection  The identification of plasma waves by VIPER is done  after detecting the time varying (oscillating) electric field  and magnetic field signals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Initially the plasma parameters  such as electron and ion number density and electron and  ion plasma temperature shall be estimated using the LP  along with the background steady state which is going to  be measured by the FGM as given in Table 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 7  Instrument /  Scientific Aim  Plasma/Field  Parameter &  Range  Measurements  Required  Langmuir  Probe (LP)  Plasma  parameter  measurements  ne;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [102 - 106 cm-3]  Te;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='1 - 1 eV]  ni (bulk);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [102 - 105  cm-3]  Ti (bulk);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='06 –  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='4 eV]  Electron & Ion  saturation  currents,  Complete I-V  characteristics  Electric Field  Sensor (EFS)  Oscillating  plasma wave  electric field  ω (ES & EM) [1  Hz - 55 kHz];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  E1 ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [mV/m]  Wave electric  field at different  frequencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Fluxgate  Magnetometer  (FGM)  Background  magnetic field  measurements  B0 ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [1 – 300 nT]  Bx1, By1, Bz1 and  Bx2, By2, Bz2  Search-coil  Magnetometer  (SCM)  Oscillating  plasma wave  magnetic field  ω (EM only) ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [1  Hz – 55 kHz]  B1 ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' [1 – 300 nT]  Wave magnetic  field at different  frequencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Here, ω is the angular frequency (= 2πf) of the wave  having frequency f, E1 and B1 are the time-varying wave  electric and magnetic fields respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' These plasma  and field parameters are to be used to estimate the plasma  characteristic frequencies such as the electron/ion plasma  frequency,  electron/ion  cyclotron  frequency  and  secondary plasma parameters as given in Table 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  Table 8  Plasma Parameters  Measured  quantities /  constants  Value  4  Electron cyclotron  frequency,  ωc = 2π (e B0) / me  B0 , e , me  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='8 × 106 B0  Hz  Ion cyclotron  frequency,  Ωc = 2π (Z e B0) / mi  B0 , mi , mp , Z  μ = mi /mp  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='52 × 103 Z  μ-1 B0 Hz  Electron plasma  frequency,  ωpe = 2π (e2 ne / me  ε0)1/2  ne , e , me ,ε0  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='98 × 103  ne  1/2 Hz  Ion plasma  frequency,  ωpi = 2π (Z2 e2 ni / mi  ε0)1/2  Z , e , ni , mi ,  ε0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='1 × 102 Z  μ-1/2 ni  1/2 Hz  Electron thermal  velocity,  vthe = (KBTe / me)1/2  KB, Te , me  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='19 × 105 Te  m/sec  Ion sound velocity,  vs = (γ Z KBTe /  mi)1/2  k , Te , mi , Z ,  γ , μ  μ = mi /mp , γ =  cp/cv  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='79 × 103 (γ  Z Te /μ)1/2  m/sec  Ion thermal velocity,  vthi = (k Ti / mi)1/2  KB, Ti , me  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='79 × 103  Ti  1/2 μ-1/2  m/sec  Debye length,  λD = (KBTe / e2 ne)1/2  KB, Te , ne , e  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='43 Te  1/2 ne 1/2 m  Alfven velocity  vA = B0 / (µ0ρ)1/2  B0 ,µ0 ,ρ, μ  ρ = nimi ,μ =  mi /mp  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='18×109 μ-  1/2 ni  1/2 B0  m/sec  Here, B0 is the background magnetic field, e is electronic  charge, me is electron mass, Z is the atomic number, mi is  ion mass, mp is proton mass, c is velocity of light in free  space, ε0 is the permittivity of the free space, KB is the  Boltzmann constant, Te is the electron temperature, γ is  the ratio of specific heats, µ0 is the permeability of the free  space, ρ is the ion mass density, ni is ion number density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='  The estimated plasma parameters and measured magnetic  field along with the frequency of the oscillating electric  and magnetic field shall be fitted in the dispersion  relations of various plasma waves that can exist around  the Venus and the outcome shall be analysed for proper  identification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' For example, the dispersion relation of an  electron plasma (or Langmuir) wave is ω2 = ωp  2 + (3/2)  k2vth  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Here, the variables are ω (measured from EFS), ωpe  (estimated from ne measured by LP), vthe (estimated from  Te measured by LP) and k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' For a given small range of k,  the dispersion relation shall be satisfied and the existence  of the wave shall be established.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
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+page_content='1819889  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' Chen, “Introduction to Plasma Physics and  Controlled Fusion”, Third Edition, Chapter 4 “Waves in  Plasma”, Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content='6 „Ion Waves‟, 1984, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
+page_content=' 91' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/QNE1T4oBgHgl3EQfagS4/content/2301.03163v1.pdf'}
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+Anisotropic Quark Stars with an Interacting Quark Equation of State within the
+Complexity Factor Formalism
+´Angel Rinc´on a ∗
+Grigoris Panotopoulos b †
+Il´ıdio Lopes c ‡
+a Departamento de F´ısica Aplicada, Universidad de Alicante,
+Campus de San Vicente del Raspeig, E-03690 Alicante, Spain;
+b Departamento de Ciencias F´ısicas, Universidad de la Frontera, Casilla 54-D, 4811186 Temuco, Chile.
+c Centro de Astrof´ısica e Gravita¸c˜ao-CENTRA, Instituto Superior T´ecnico-IST,
+Universidade de Lisboa-UL, Av. Rovisco Pais, 1049-001 Lisboa, Portugal.
+Within the framework of Einstein’s General Relativity we study strange quark stars assuming
+an interacting equation-of-state. Taking into account the presence of anisotropies in a sphere made
+of ultra dense matter, we employ the formalism based on the complexity factor. We integrate the
+structure equations numerically imposing the appropriate conditions both at the center and at the
+surface of the stars, thus obtaining interior solutions describing hydrostatic equilibrium. Making use
+of well-established criteria, we demonstrate that the solutions obtained here are well behaved and
+realistic. A comparison with another, more conventional approach, is made as well. Our numerical
+results are summarized in a number of figures.
+I.
+INTRODUCTION
+Unlike many other forms of matter, relativistic compact stars [1–4], which are formed during the final stages of
+stellar evolution, are excellent cosmic probes to study the properties of matter under exceptionally extreme conditions.
+Supernova explosions, either Type Ia or Type II, are the best known mechanisms to produce compact stars. Type Ia
+Supernovas occur when white dwarfs accrete matter from a companion in a binary (e.g., [5]). Type II corresponds to
+the core collapse of massive stars; although the mass range is not well defined, the current estimates predict a range
+from 8 to 30 solar masses (e.g., [6]). Although the most likely stellar remnants of these events are neutron stars,
+they could also form many other kinds of compact stars. Matter inside such objects is characterized by ultra-high
+mass/energy densities, for which the usual description of astrophysical plasmas in terms of non-relativistic Newtonian
+fluids is inadequate. Therefore, those very dense compact objects are relativistic in nature, and as such they are only
+properly described within the framework of Einstein’s General Relativity (GR) [7].
+Neutron stars (NSs) are exciting astronomical objects, since understanding and explaining their properties, as well
+as their observed complex phenomena, require bringing together several scientific disciplines and lines of research,
+such as nuclear particle physics, astrophysics and gravitational physics. As NSs are the densest objects in the Universe
+after black holes, they can be used to probe, test and study properties of matter in an extreme gravitational regime,
+conditions that cannot be reproduced in earth-based experiments. For instance, supermassive star core collapses
+are known to trigger a complex network of physical processes that amplify magnetic fields up to tens of tera-tesla.
+This dramatic event involves neutrino emissions, convection [8] and magnetorotational instabilities [9], accompanied
+by a turbulent dynamo affecting the synthesis of heavy nuclides by r- and other atomic process nuclei (e.g., [10]).
+The result is the formation of a compact star with a strong magnetic field in its interior, possibly with a high degree
+of anisotropy in the local equation of state.
+Therefore, those objects constitute an excellent cosmic laboratory to explore and possibly constrain non-conventional
+physics, as well as alternative theories of gravity.
+Strange quark stars (QSs) [11–16], although at the moment theorized and less standard astronomical objects than
+NSs, may be viewed as ultra-compact neutron stars. Since quark matter is by assumption absolutely stable, it may be
+the true ground state of hadronic matter [17, 18]. Therefore, this new class of relativistic compact objects has been
+proposed as an alternative to typical NSs. Though as of today they remain hypothetical objects, quarks stars cannot
+conclusively be ruled out yet. In fact investigating their properties is well motivated, both from the theoretical and
+observational point of view. For example, there are some claims in the literature that there are currently some observed
+compact objects exhibiting peculiar features, such as small radii for instance, that cannot be explained by the usual
+hadronic equations-of-state used in NS studies, see e.g., [19–21], and also Table 5 of [14] and the references therein.
+The present study is also relevant for the possible implications to understand the nature of compact stars. Recently,
+∗ angel.rincon@ua.es
+† grigorios.panotopoulos@ufrontera.cl
+‡ ilidio.lopes@tecnico.ulisboa.pt
+arXiv:2301.13684v1  [gr-qc]  31 Jan 2023
+
+2
+a few authors suggested that strange matter could exist in the core of NS-hybrid stars [22–24], while others claim such
+stars are almost indistinguishable from NS [25]. In addition to that, strange quark stars may explain some puzzling
+super-luminous supernovae [26, 27], which occur in about one out of every 1000 supernovae explosions, and which
+are more than 100 times more luminous than regular supernovae. One plausible explanation is that since quark
+stars are much more stable than NSs, they could explain the origin of the huge amount of energy released in super-
+luminous supernovae. Many works have been recently proposed to validate their existence in different astrophysical
+scenarios [28, 29].
+In studies of compact objects, the authors usually focus their attention on relativistic stars made of isotropic matter,
+such that Pr = PT , where Pr is the radial pressure, and PT is the tangential pressure. However, celestial bodies are
+not necessarily made of isotropic matter alone. As a matter of fact, it is now known that under certain conditions
+the fluid representing matter content may become anisotropic. The review article of Ruderman [30] mentioned for
+the first time such a possibility: the author observed that interactions among relativistic particles in a very dense
+nuclear matter medium could generate a non-vanishing anisotropic factor. Studies on anisotropies in relativistic stars
+received a boost thanks to the subsequent work of [31]. Indeed, anisotropies may arise in many different physical
+situations of a dense matter medium, such as in the presence of strong magnetic fields [32, 33], in phase transitions [34],
+in pion condensation [35], slow rotation [36], viscosity-induced anisotropy [37], a mixture of two fluids [38] or in the
+presence of type 3A super-fluid [39] (see also [40–42] and the references therein for more recent works on the topic).
+In those works, relativistic models of anisotropic quark stars were studied, and the energy conditions were shown to
+be fulfilled. In particular, in [40] an exact analytic solution was obtained, in [41] an attempt was made to find a
+singularity-free solution to Einstein’s field equations and in [42] the Homotopy Perturbation Method was employed,
+which is a tool that facilitates the ability to tackle Einstein’s field equations. Furthermore, alternative approaches
+have been considered to incorporate new anisotropic solutions to already known isotropic ones [43–45].
+In this work we propose to obtain interior solutions of relativistic stars, and in particular, of quark stars made
+of anisotropic matter, within the approach based on the complexity factor formalism. Originally, the new definition
+of the complexity factor was only investigated from a mathematical point of view, see [46–49] and the references
+therein. However, the real usefulness of such a definition becomes evident when we make use of it as a supplementary
+condition to close the set of structure equations describing the hydrostatic equilibrium of a self-gravitating spherical
+configuration. Moreover, the complexity factor may be used as a self-consistent way to incorporate anisotropies, which
+are generated in the presence of ultra dense matter in relativistic objects, as already mentioned before.
+The plan of our work in the present article is the following: after this introductory section, we review the description
+of relativistic stars in the framework of Einstein’s theory in Section II, while in the third section we present the
+vanishing complexity formalism. Next, in Section IV we show and discuss our numerical results, and finally we finish
+our work with some concluding remarks in the last section. We work in geometrical units where G = 1 = c, and we
+adopt the mostly negative metric signature in four space-time dimensions, namely +, −, −, −.
+II.
+RELATIVISTIC STARS IN GENERAL RELATIVITY
+Let us start considering a static and spherically symmetric object in an anisotropic background bounded by a
+spherical surface Σ. Assuming a line element that is written in Schwarzschild-like coordinates, i.e.,
+ds2 = eνdt2 − eλdr2 − r2dΩ2.
+(1)
+The functions ν(r) and λ(r) are the metric potentials and depend on the radial coordinate only, whereas dΩ2 ≡
+�
+dθ2 + sin2 θdφ2�
+corresponds to the element of solid angle. We will take: x0 = t; x1 = r; x2 = θ; x3 = φ. In the
+absence of a cosmological constant term, the classical Einstein field equations acquire the simple form:
+Gν
+µ = 8πGT ν
+µ ,
+(2)
+with G being Newton’s constant (taken to be unity in the following for simplicity). Now, in the co-moving frame,
+the physical matter content is an anisotropic fluid of energy density ρ, radial pressure Pr, and tangential pressure P⊥,
+i.e., the covariant energy–momentum tensor in (local) Minkowski coordinates is then written as T µ
+ν = {ρ, Pr, P⊥, P⊥}
+and the field equations can be written as:
+ρ = − 1
+8π
+�
+− 1
+r2 + e−λ
+� 1
+r2 − λ′
+r
+��
+,
+(3)
+Pr = − 1
+8π
+� 1
+r2 − e−λ
+� 1
+r2 + ν′
+r
+��
+,
+(4)
+P⊥ =
+1
+32π e−λ
+�
+2ν′′ + ν′2 − λ′ν′ + 2ν′ − λ′
+r
+�
+,
+(5)
+
+3
+where the symbol prime (′) denotes the derivative in relation to r.
+Combining Equations (3)–(5), we obtain the hydrostatic equilibrium equation, best known as the generalized
+Tolman–Opphenheimer–Volkoff equation, which takes the simplest form
+− 1
+2ν′ (ρ + Pr) − P ′
+r + 2
+r (P⊥ − Pr) = 0.
+(6)
+Such an equation can be understood as the balance between the following three forces: (i) gravitational, Fg, (ii)
+hydrostatic, Fr and (iii) anisotropic, Fp, defined according to the following expressions
+Fg = −ν′ (ρ + Pr)
+2
+,
+Fr = −P ′
+r
+and
+Fp = 2Π
+r .
+(7)
+At this point it should be mentioned that the anisotropic factor, Π (sometimes also referred to as ∆), is defined as
+usual, i.e., Π = P⊥ − Pr. Accordingly, Equation (6), now reads
+Fg + Fr + Fp = 0.
+(8)
+To clarify the situation, the last equation implies that this compact star results from the equilibrium between these
+three different forces, as is mentioned in Ref. [50]. In particular, if Fp = 0, we obtain the standard TOV equation.
+Moreover, in cases where P⊥ > Pr (or equivalently Π > 0), Fp > 0 causes a repulsive force in Equation (8) that
+counteracts the attractive force given by the combination Fg +Fr. On the contrary, if we consider the case of P⊥ < Pr
+(or Π < 0), Fp < 0 is also an attractive force that adds to the other ones.
+To remove the ν′-dependence in Equation (6), we will take advantage of the following relation
+1
+2ν′ = m + 4πPrr3
+r (r − 2m) ,
+(9)
+and we then rewrite the generalized TOV equation as
+P ′
+r = −(m + 4πPrr3)
+r (r − 2m)
+(ρ + Pr) + 2
+r (P⊥ − Pr) .
+(10)
+In addition, m is the mass function, obtained by:
+R3
+232 = 1 − e−λ = 2m
+r ,
+(11)
+or,
+m = 4π
+� r
+0
+˜r2ρ d˜r.
+(12)
+The energy-momentum tensor can be rewritten as follows
+T µ
+ν = ρuµuν − Phµ
+ν + Πµ
+ν.
+(13)
+From the expression of T ν
+µ , we have to point out that the four-velocity is taken to be uµ = (e− ν
+2 , 0, 0, 0), and the
+four-acceleration is aα = uα
+;βuβ, whose any non-vanishing component is a1 = −ν′/2.
+Subsequently, the set
+{Πµ
+ν, Π, hµ
+ν, sµ, P} is defined as
+Πµ
+ν = Π
+�
+sµsν + 1
+3hµ
+ν
+�
+(14)
+Π = P⊥ − Pr
+(15)
+hµ
+ν = δµ
+ν − uµuν
+(16)
+sµ = (0, e− λ
+2 , 0, 0)
+(17)
+P ≡ 1
+3
+�
+Pr + 2P⊥
+�
+(18)
+with the properties sµuµ = 0 and sµsµ = −1. For the exterior solution, we match the problem with Schwarzschild
+space-time, i.e.,
+ds2 =
+�
+1 − 2M
+r
+�
+dt2 −
+�
+1 − 2M
+r
+�−1
+dr2 − r2dΩ2.
+(19)
+
+4
+We have to complete the problem with the appropriate matching conditions on the surface r = R = constant, with R
+being the radius of the star. Thus, by demanding continuity of the first and the second fundamental forms across
+that surface, we have
+eνΣ = 1 − 2M
+R ,
+(20)
+e−λΣ = 1 − 2M
+R ,
+(21)
+[Pr]Σ = 0,
+(22)
+where M is the mass of the star, while the subscript Σ indicates that the quantity is evaluated on the boundary
+surface Σ. To finish, let us mention that the last three equations are the necessary and sufficient conditions for a
+smooth matching of the interior and exterior solutions, (1) and (19) respectively, on the surface Σ.
+III.
+VANISHING COMPLEXITY FACTOR FORMALISM
+The present section summarizes the main ingredient behind the complexity factor formalism and its importance
+in astrophysical scenarios. To start, we should mention the original paper of Luis Herrera (L.H.) [51], in which the
+study of static anisotropic self-gravitating objects was performed. In that paper, the author introduced a modern
+definition of complexity and was motivated mainly by two concrete problems present in old descriptions: (i) the
+probability distribution is replaced by the energy density of the fluid distribution [52], and (ii) a complete inclusion
+of the components of the energy density fluid is missing, and the unique inclusion is the energy density of the fluid
+(ignoring possible additional contributions such as pressure). These two critical points are, in principle, the primary
+motivation used by L.H. to modify the more traditional complexity definition.
+Albeit the standard definition of complexity was first introduced as a mathematical treatment only (see [46–49]
+and the references therein), its importance becomes evident when we recognize that such a condition can be used as
+an alternative route to bypass a standard ingredient in stellar interiors: the election of certain profiles of the system.
+Thus, the complexity factor formalism, or, more precisely, its simplified version, namely, when the complexity factor
+is zero, allows us to close the system and obtain novel and non-trivial spherically symmetric solutions unknown up
+to now. Thus, the vanishing complexity formalism offers a parallel way to deal with anisotropies in relativistic stars
+(see for instance [53, 54]).
+Now, let us move to the basic details behind the method. The essence of the complexity factor formalism emerges
+when we check the orthogonal splitting of the Riemann tensor for static self-gravitating fluids with spherical symmetry
+(please, for a detailed explanation, see [51] and also [55]). The (orthogonal) decomposition of the Riemann tensor is
+usually tedious labor and was well-studied in the original paper, thus we will avoid repetitions. We will take advantage
+of some helpful definitions:
+Yαβ = Rαγβδuγuδ,
+(23)
+Zαβ = R∗
+αγβδuγuδ = 1
+2ηαγϵµRϵµ
+βδuγuδ,
+(24)
+Xαβ = R∗
+αγβδuγuδ = 1
+2η
+ϵµ
+αγ
+R∗
+ϵµβδuγuδ,
+(25)
+where the symbol ∗ is the dual tensor, i.e.,
+R∗
+αβγδ = 1
+2ηϵµγδR
+ϵµ
+αβ
+(26)
+and ηϵµγδ is the well-known Levi–Civita tensor. Utilizing the decomposition of the Riemann tensor, the set of tensors
+{Yαβ, Zαβ, Xαβ} can be written in a convenient way, in terms of the physical variables, namely,
+Yαβ = 4π
+3 (ρ + 3P)hαβ + 4πΠαβ + Eαβ,
+(27)
+Zαβ = 0,
+(28)
+Xαβ = 8π
+3 ρhαβ + 4πΠαβ − Eαβ.
+(29)
+Also, the tensor Eαβ (defined as Eαβ = Cαγβδuγuδ) can be written as
+Eαβ = E
+�
+sαsβ + 1
+3hαβ
+�
+,
+(30)
+
+5
+where E is precisely
+E = −e−λ
+4
+�
+ν′′ + ν′2 − λ′ν′
+2
+− ν′ − λ′
+r
++ 2(1 − eλ)
+r2
+�
+,
+(31)
+satisfying the following properties:
+Eα
+α = 0,
+Eαγ = E(αγ),
+Eαγuγ = 0.
+(32)
+At this point it is essential to mention that the tensors {Yαβ, Zαβ, Xαβ} can be expressed in terms of alternative
+scalar functions, as was previously discussed in [56]. Now, consider the following tensors: Xαβ and Yαβ in the static
+case. Based on that, it is possible to define the so-called structure scalars XT , XT F , YT , YT F , in terms of the physical
+variables, as follows:
+XT = 8πρ,
+(33)
+XT F = 4π
+r3
+� r
+0
+˜r3ρ′d˜r,
+(34)
+YT = 4π(ρ + 3Pr − 2Π),
+(35)
+YT F = 8πΠ − 4π
+r3
+� r
+0
+˜r3ρ′d˜r.
+(36)
+From Equations (34)–(36), the local anisotropy of pressure is obtained utilizing XT F and YT F with help of the
+following relation:
+8πΠ = XT F + YT F .
+(37)
+The vanishing complexity condition, YT F = 0, implies the following relation between the energy density and the
+anisotropic factor
+Π(r) =
+1
+2r3
+� r
+0
+˜r3ρ′(˜r)d˜r.
+(38)
+Thus, for a given density profile ρ(r), we can compute the anisotropic factor for a self-gravitating system. Notice that
+the classical formalism, i.e., selecting a suitable form of the anisotropic factor by hand (among other alternatives), has
+also been significantly investigated over the years (see, for instance, [29, 43, 57–67] and the references therein). As the
+complexity factor formalism in the context of relativistic stars is so helpful, we will follow this idea and contrast the
+results obtained following such an approach with solutions coming from the canonical method, i.e., taking by hand
+the anisotropic factor, for instance.
+IV.
+RESULTS AND DISCUSSION
+In the present paper we have investigated within GR anisotropic stars made of quark matter in light of the vanishing
+complexity formalism. In particular, we compute numerically interior solutions of realistic spherical configurations of
+anisotropic matter, and we compare our solution against a more conventional approach, i.e., assuming an ansatz for
+the anisotropic factor by hand. For quark matter we adopt the interacting equation-of-state, Pr(ρ), given by [68, 69]
+Pr = 1
+3 (ρ − 4B) − m2
+s
+3π
+�
+ρ − B
+a4
++ m4
+s
+12π2
+�
+1 − 1
+a4
++ 3 ln
+�
+8π
+3m2s
+�
+ρ − B
+a4
+��
+,
+(39)
+where Pr is the radial pressure, and ρ is the energy density of homogeneously distributed quark matter (also to
+O (m4
+s) in the Bag model).
+For the purpose of the present analysis, following Beringer et al [70], we take the
+strange quark mass (ms) to be 100 MeV, while the accepted values of the bag constant, B, lie within the range
+57 ≤ B ≤ 92 MeV/fm3 [71, 72]. Also, the parameter a4 comes from QCD corrections on the pressure of the quark-free
+Fermi sea, and it is directly related with the mass-radius relations of quark stars. Note that as far as the EoS is
+
+6
+concerned, only the radial pressure is relevant. The tangential pressure has already been defined in the Introduction
+as well as after Equation (2).
+After the numerical computations, we display in a number of figures, several quantities of interest. In Figures 1–4,
+on the x-axis we put the normalized radial coordinate r/R, while on the y-axis we put the quantities of interest,
+such as the mass of the star in solar masses, dimensionless quantities (for instance, the relativistic adiabatic index),
+and normalized quantities (e.g., the pressures and the energy density as well as the anisotropic factor in units of the bag
+constant, B). The curves exhibit the usual behaviour observed in interior solutions describing hydrostatic equilibrium.
+In particular, the mass function increases starting from 0 at the centre, while its mass at r = R corresponds to the
+star’s mass. The energy density and the pressures start from their central value and monotonically decrease until the
+radial pressure vanishes at the star’s surface. In contrast, the energy density acquires a surface value. The energy
+density and the pressures remain positive throughout the star, while the energy density always remains larger than
+the pressures, such that the energy conditions are fulfilled. Moreover, both sound speeds vary slowly with the radial
+coordinate, taking values within the range 0–1 throughout the star, so causality is not violated. The anisotropic factor
+turns out to be negative, which is always the case within the vanishing complexity formalism. Finally, the relativistic
+adiabatic index increases monotonically and rapidly acquires large values as we approach the surface of the star.
+At the same time, it always remains larger than the Newtonian value Γ0 = 4/3. In particular, we notice that: (i)
+the mass function increase, the anisotropic factor decrease and the energy density and pressures decrease throughout
+the star, (ii) the speed of sound, radial and tangential, increase and decrease, respectively, and both are lower than
+c2
+0 ≡ 1, the relativistic adiabatic index, Γ(r), increase and it is always higher than Γ0 ≡ 4/3, (iii) the corresponding
+energy conditions are also satisfied. Thus, in light of the these numerical results, we can confirm that the complexity
+factor formalism is a solid approach to obtain well-defined solutions in the context of compact stars.
+As a supplementary independent check, we have obtained, numerically again, interior solutions using a more stan-
+dard approach, i.e., adding external constraints to close the system of differential equations. As a toy model, we have
+considered an anisotropic factor, Π(r), as follows [73–77]
+Π(r) = κ Pr(r) [1 − e−λ(r)] = κ Pr(r) 2m
+r ,
+(40)
+characterized by a dimensionless parameter, κ, which encodes the strength of the anisotropy. Also, we consider several
+values from κ = −1 to κ = −10.
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+0.00
+0.05
+0.10
+0.15
+0.20
+r/R
+m(r)/M☉
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+-0.30
+-0.25
+-0.20
+-0.15
+-0.10
+-0.05
+0.00
+r/R
+Δ(r)/B
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+-1
+0
+1
+2
+3
+4
+5
+6
+r/R
+ρ(r)/B
+pr(r)/B
+pt(r)/B
+FIG. 1: Anisotropic SQ stars within the complexity factor: mass function in solar masses (left panel), anisotropic factor
+(middle panel), and energy density and pressures (right panel) versus the radial coordinate throughout the star.
+Our main results may be summarized as follows: the conventional method predicts more massive objects in com-
+parison to the stars within the vanishing complexity formalism. The mass of the object decreases with the anisotropic
+factor, approaching the mass corresponding to the method based on vanishing complexity. Eventually, causality is
+violated as the tangential speed of sound becomes negative, and therefore the solution is no longer realistic.
+Finally, in Figure (5), we show the mass-to-radius relationship for anisotropic stars for both approaches. First
+we study anisotropies within the vanishing complexity formalism, and we obtain the curve in red. Next, when we
+consider the conventional method, since now the ansatz for the anisotropic factor is characterized by a continuous
+parameter, we can observe the impact of that parameter on the profiles, corresponding to the other 3 curves in the
+figure. Increasing the anisotropy, the profile is gradually shifted towards the one corresponding to complexity. But at
+some point causality is violated, and therefore the solution is not realistic/viable any more. That is precisely the
+point where we must stop. The last allowed profile remains quite far away from the one obtained within complexity.
+Before we conclude our work, a final comment is in order. In the present article our main goal was to study the
+implications of the formalism based on vanishing complexity factor, and compare to a more standard approach. It
+would be interesting, however, to study the stability of anisotropic stars as well, analyzing radial oscillation modes
+
+7
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+r/R
+c02
+cr2
+ct2
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+0
+10
+20
+30
+40
+50
+60
+r/R
+Γ(r)
+Γ0
+FIG. 2: Anisotropic SQ stars within the complexity factor: speed of sounds (left panel) and relativistic adiabatic index (right
+panel) versus the radial coordinate throughout the star. The horizontal straight line corresponds to the value Γ0 = 4/3.
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+4.2
+4.3
+4.4
+4.5
+4.6
+4.7
+4.8
+4.9
+r/R
+(ρ(r) - pr(r) - 2pt(r))/B
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+4
+5
+6
+7
+8
+r/R
+(ρ(r) + pr(r) + 2pt(r))/B
+FIG. 3:
+Anisotropic QS stars within the complexity factor: energy conditions versus the radial coordinate throughout the
+star.
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+0.0
+0.2
+0.4
+0.6
+r/R
+m(r)/M☉
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+-0.30
+-0.25
+-0.20
+-0.15
+-0.10
+-0.05
+0.00
+r/R
+Δ(r)/B
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+r/R
+cs2
+FIG. 4:
+Anisotropic QS stars considering a more standard approach and assuming (i) κ = −1 (dotted red line), (ii) κ = −6
+(dashed red line), (iii) κ = −10 (dot-dashed red line), for: mass function in solar masses (left panel), anisotropic factor (middle
+panel), and sound speeds (right panel) versus the radial coordinate throughout the star. In particular, for the right-hand panel,
+we have plotted tangential (red color) and radial (cyan color) c2
+s, respectively. For comparison, we added our solution utilizing
+the complexity formalism (solid red line).
+and computing the corresponding frequencies. As this investigation lies beyond the scope of the present work, we
+propose to postpone it for the time being, and we hope to be able to do so in the future.
+
+8
+Complexity Method
+Conventional Method (κ = -1)
+Conventional Method (κ = -3)
+Conventional Method (κ = -6)
+3
+4
+5
+6
+7
+8
+9
+0.0
+0.2
+0.4
+0.6
+0.8
+1.0
+1.2
+1.4
+R(km)
+M (M⊙)
+FIG. 5: Mass-radius profiles obtained by two alternative methods: (i) the vanishing complexity method (solid red line), and (ii)
+the conventional method for: κ = −1 (cyan dashed line), κ = −3 (dashed purple line), and κ = −6 (dot-dashed orange line).
+V.
+CONCLUSIONS
+To summarize our work, in the present article we have obtained interior solutions of strange quark stars made of
+anisotropic matter. Assuming an interacting equation-of-state, we have taken into account the presence of anisotropies
+generated by ultra dense quark matter. The anisotropic factor has been introduced employing the formalism based on
+the complexity factor, and the structure equations have been integrated numerically. The solutions have been shown to
+be well-behaved and realistic. Moreover, we have made a comparison with another more conventional approach, where
+the form of the anisotropic factor is introduced by hand. Finally, we have obtained the mass-to-radius relationships
+within both methods, namely (i) employing the complexity formalism (where there are no free parameters), and (ii)
+adopting a certain form for the anisotropic factor (used in previous works, characterized by a free parameter). Our
+results show that as the anisotropy inceases, thus varying the free parameter, the profile is shifted towards the one
+corresponding to the complexity factor formalism.
+VI.
+ACKNOWLEDGMENTS
+A.R. is funded by the Mar´ıa Zambrano contract ZAMBRANO 21-25 (Spain). I.L. thanks the Funda¸c˜ao para a
+Ciˆencia e Tecnologia (FCT), Portugal, for the financial support to the Center for Astrophysics and Gravitation (CEN-
+TRA/IST/ULisboa) through the Grant Project No. UIDB/00099/2020 and Grant No. PTDC/FIS-AST/28920/2017.
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+
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+page_content='Anisotropic Quark Stars with an Interacting Quark Equation of State within the  Complexity Factor Formalism  ´Angel Rinc´on a ∗  Grigoris Panotopoulos b †  Il´ıdio Lopes c ‡  a Departamento de F´ısica Aplicada, Universidad de Alicante,  Campus de San Vicente del Raspeig, E-03690 Alicante, Spain;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  c Centro de Astrof´ısica e Gravita¸c˜ao-CENTRA, Instituto Superior T´ecnico-IST,  Universidade de Lisboa-UL, Av.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  Within the framework of Einstein’s General Relativity we study strange quark stars assuming  an interacting equation-of-state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Taking into account the presence of anisotropies in a sphere made  of ultra dense matter, we employ the formalism based on the complexity factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' We integrate the  structure equations numerically imposing the appropriate conditions both at the center and at the  surface of the stars, thus obtaining interior solutions describing hydrostatic equilibrium.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Making use  of well-established criteria, we demonstrate that the solutions obtained here are well behaved and  realistic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' A comparison with another, more conventional approach, is made as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Our numerical  results are summarized in a number of figures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  INTRODUCTION  Unlike many other forms of matter, relativistic compact stars [1–4], which are formed during the final stages of  stellar evolution, are excellent cosmic probes to study the properties of matter under exceptionally extreme conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Supernova explosions, either Type Ia or Type II, are the best known mechanisms to produce compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Type Ia  Supernovas occur when white dwarfs accrete matter from a companion in a binary (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', [5]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Type II corresponds to  the core collapse of massive stars;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' although the mass range is not well defined, the current estimates predict a range  from 8 to 30 solar masses (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', [6]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Although the most likely stellar remnants of these events are neutron stars,  they could also form many other kinds of compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Matter inside such objects is characterized by ultra-high  mass/energy densities, for which the usual description of astrophysical plasmas in terms of non-relativistic Newtonian  fluids is inadequate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Therefore, those very dense compact objects are relativistic in nature, and as such they are only  properly described within the framework of Einstein’s General Relativity (GR) [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Neutron stars (NSs) are exciting astronomical objects, since understanding and explaining their properties, as well  as their observed complex phenomena, require bringing together several scientific disciplines and lines of research,  such as nuclear particle physics, astrophysics and gravitational physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' As NSs are the densest objects in the Universe  after black holes, they can be used to probe, test and study properties of matter in an extreme gravitational regime,  conditions that cannot be reproduced in earth-based experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' For instance, supermassive star core collapses  are known to trigger a complex network of physical processes that amplify magnetic fields up to tens of tera-tesla.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  This dramatic event involves neutrino emissions, convection [8] and magnetorotational instabilities [9], accompanied  by a turbulent dynamo affecting the synthesis of heavy nuclides by r- and other atomic process nuclei (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', [10]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  The result is the formation of a compact star with a strong magnetic field in its interior, possibly with a high degree  of anisotropy in the local equation of state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Therefore, those objects constitute an excellent cosmic laboratory to explore and possibly constrain non-conventional  physics, as well as alternative theories of gravity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Strange quark stars (QSs) [11–16], although at the moment theorized and less standard astronomical objects than  NSs, may be viewed as ultra-compact neutron stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Since quark matter is by assumption absolutely stable, it may be  the true ground state of hadronic matter [17, 18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Therefore, this new class of relativistic compact objects has been  proposed as an alternative to typical NSs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Though as of today they remain hypothetical objects, quarks stars cannot  conclusively be ruled out yet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In fact investigating their properties is well motivated, both from the theoretical and  observational point of view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' For example, there are some claims in the literature that there are currently some observed  compact objects exhibiting peculiar features, such as small radii for instance, that cannot be explained by the usual  hadronic equations-of-state used in NS studies, see e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', [19–21], and also Table 5 of [14] and the references therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  The present study is also relevant for the possible implications to understand the nature of compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Recently,  ∗ angel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='rincon@ua.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='es  † grigorios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='panotopoulos@ufrontera.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='cl  ‡ ilidio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='lopes@tecnico.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='ulisboa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='pt  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='13684v1  [gr-qc]  31 Jan 2023  2  a few authors suggested that strange matter could exist in the core of NS-hybrid stars [22–24], while others claim such  stars are almost indistinguishable from NS [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In addition to that, strange quark stars may explain some puzzling  super-luminous supernovae [26, 27], which occur in about one out of every 1000 supernovae explosions, and which  are more than 100 times more luminous than regular supernovae.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' One plausible explanation is that since quark  stars are much more stable than NSs, they could explain the origin of the huge amount of energy released in super-  luminous supernovae.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Many works have been recently proposed to validate their existence in different astrophysical  scenarios [28, 29].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  In studies of compact objects, the authors usually focus their attention on relativistic stars made of isotropic matter,  such that Pr = PT , where Pr is the radial pressure, and PT is the tangential pressure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' However, celestial bodies are  not necessarily made of isotropic matter alone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' As a matter of fact, it is now known that under certain conditions  the fluid representing matter content may become anisotropic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The review article of Ruderman [30] mentioned for  the first time such a possibility: the author observed that interactions among relativistic particles in a very dense  nuclear matter medium could generate a non-vanishing anisotropic factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Studies on anisotropies in relativistic stars  received a boost thanks to the subsequent work of [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Indeed, anisotropies may arise in many different physical  situations of a dense matter medium, such as in the presence of strong magnetic fields [32, 33], in phase transitions [34],  in pion condensation [35], slow rotation [36], viscosity-induced anisotropy [37], a mixture of two fluids [38] or in the  presence of type 3A super-fluid [39] (see also [40–42] and the references therein for more recent works on the topic).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  In those works, relativistic models of anisotropic quark stars were studied, and the energy conditions were shown to  be fulfilled.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In particular, in [40] an exact analytic solution was obtained, in [41] an attempt was made to find a  singularity-free solution to Einstein’s field equations and in [42] the Homotopy Perturbation Method was employed,  which is a tool that facilitates the ability to tackle Einstein’s field equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Furthermore, alternative approaches  have been considered to incorporate new anisotropic solutions to already known isotropic ones [43–45].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  In this work we propose to obtain interior solutions of relativistic stars, and in particular, of quark stars made  of anisotropic matter, within the approach based on the complexity factor formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Originally, the new definition  of the complexity factor was only investigated from a mathematical point of view, see [46–49] and the references  therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' However, the real usefulness of such a definition becomes evident when we make use of it as a supplementary  condition to close the set of structure equations describing the hydrostatic equilibrium of a self-gravitating spherical  configuration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Moreover, the complexity factor may be used as a self-consistent way to incorporate anisotropies, which  are generated in the presence of ultra dense matter in relativistic objects, as already mentioned before.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  The plan of our work in the present article is the following: after this introductory section, we review the description  of relativistic stars in the framework of Einstein’s theory in Section II, while in the third section we present the  vanishing complexity formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Next, in Section IV we show and discuss our numerical results, and finally we finish  our work with some concluding remarks in the last section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' We work in geometrical units where G = 1 = c, and we  adopt the mostly negative metric signature in four space-time dimensions, namely +, −, −, −.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  RELATIVISTIC STARS IN GENERAL RELATIVITY  Let us start considering a static and spherically symmetric object in an anisotropic background bounded by a  spherical surface Σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Assuming a line element that is written in Schwarzschild-like coordinates, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=',  ds2 = eνdt2 − eλdr2 − r2dΩ2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (1)  The functions ν(r) and λ(r) are the metric potentials and depend on the radial coordinate only, whereas dΩ2 ≡  �  dθ2 + sin2 θdφ2�  corresponds to the element of solid angle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' We will take: x0 = t;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' x1 = r;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' x2 = θ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' x3 = φ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In the  absence of a cosmological constant term, the classical Einstein field equations acquire the simple form:  Gν  µ = 8πGT ν  µ ,  (2)  with G being Newton’s constant (taken to be unity in the following for simplicity).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Now, in the co-moving frame,  the physical matter content is an anisotropic fluid of energy density ρ, radial pressure Pr, and tangential pressure P⊥,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', the covariant energy–momentum tensor in (local) Minkowski coordinates is then written as T µ  ν = {ρ, Pr, P⊥, P⊥}  and the field equations can be written as:  ρ = − 1  8π  �  − 1  r2 + e−λ  � 1  r2 − λ′  r  ��  ,  (3)  Pr = − 1  8π  � 1  r2 − e−λ  � 1  r2 + ν′  r  ��  ,  (4)  P⊥ =  1  32π e−λ  �  2ν′′ + ν′2 − λ′ν′ + 2ν′ − λ′  r  �  ,  (5)  3  where the symbol prime (′) denotes the derivative in relation to r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Combining Equations (3)–(5), we obtain the hydrostatic equilibrium equation, best known as the generalized  Tolman–Opphenheimer–Volkoff equation, which takes the simplest form  − 1  2ν′ (ρ + Pr) − P ′  r + 2  r (P⊥ − Pr) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (6)  Such an equation can be understood as the balance between the following three forces: (i) gravitational, Fg, (ii)  hydrostatic, Fr and (iii) anisotropic, Fp, defined according to the following expressions  Fg = −ν′ (ρ + Pr)  2  ,  Fr = −P ′  r  and  Fp = 2Π  r .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (7)  At this point it should be mentioned that the anisotropic factor, Π (sometimes also referred to as ∆), is defined as  usual, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', Π = P⊥ − Pr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Accordingly, Equation (6), now reads  Fg + Fr + Fp = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (8)  To clarify the situation, the last equation implies that this compact star results from the equilibrium between these  three different forces, as is mentioned in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' [50].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In particular, if Fp = 0, we obtain the standard TOV equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Moreover, in cases where P⊥ > Pr (or equivalently Π > 0), Fp > 0 causes a repulsive force in Equation (8) that  counteracts the attractive force given by the combination Fg +Fr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' On the contrary, if we consider the case of P⊥ < Pr  (or Π < 0), Fp < 0 is also an attractive force that adds to the other ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  To remove the ν′-dependence in Equation (6), we will take advantage of the following relation  1  2ν′ = m + 4πPrr3  r (r − 2m) ,  (9)  and we then rewrite the generalized TOV equation as  P ′  r = −(m + 4πPrr3)  r (r − 2m)  (ρ + Pr) + 2  r (P⊥ − Pr) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (10)  In addition, m is the mass function, obtained by:  R3  232 = 1 − e−λ = 2m  r ,  (11)  or,  m = 4π  � r  0  ˜r2ρ d˜r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (12)  The energy-momentum tensor can be rewritten as follows  T µ  ν = ρuµuν − Phµ  ν + Πµ  ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (13)  From the expression of T ν  µ , we have to point out that the four-velocity is taken to be uµ = (e− ν  2 , 0, 0, 0), and the  four-acceleration is aα = uα  ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='βuβ, whose any non-vanishing component is a1 = −ν′/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Subsequently, the set  {Πµ  ν, Π, hµ  ν, sµ, P} is defined as  Πµ  ν = Π  �  sµsν + 1  3hµ  ν  �  (14)  Π = P⊥ − Pr  (15)  hµ  ν = δµ  ν − uµuν  (16)  sµ = (0, e− λ  2 , 0, 0)  (17)  P ≡ 1  3  �  Pr + 2P⊥  �  (18)  with the properties sµuµ = 0 and sµsµ = −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' For the exterior solution, we match the problem with Schwarzschild  space-time, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=',  ds2 =  �  1 − 2M  r  �  dt2 −  �  1 − 2M  r  �−1  dr2 − r2dΩ2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (19)  4  We have to complete the problem with the appropriate matching conditions on the surface r = R = constant, with R  being the radius of the star.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Thus, by demanding continuity of the first and the second fundamental forms across  that surface, we have  eνΣ = 1 − 2M  R ,  (20)  e−λΣ = 1 − 2M  R ,  (21)  [Pr]Σ = 0,  (22)  where M is the mass of the star, while the subscript Σ indicates that the quantity is evaluated on the boundary  surface Σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' To finish, let us mention that the last three equations are the necessary and sufficient conditions for a  smooth matching of the interior and exterior solutions, (1) and (19) respectively, on the surface Σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  VANISHING COMPLEXITY FACTOR FORMALISM  The present section summarizes the main ingredient behind the complexity factor formalism and its importance  in astrophysical scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' To start, we should mention the original paper of Luis Herrera (L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=') [51], in which the  study of static anisotropic self-gravitating objects was performed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In that paper, the author introduced a modern  definition of complexity and was motivated mainly by two concrete problems present in old descriptions: (i) the  probability distribution is replaced by the energy density of the fluid distribution [52], and (ii) a complete inclusion  of the components of the energy density fluid is missing, and the unique inclusion is the energy density of the fluid  (ignoring possible additional contributions such as pressure).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' These two critical points are, in principle, the primary  motivation used by L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' to modify the more traditional complexity definition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Albeit the standard definition of complexity was first introduced as a mathematical treatment only (see [46–49]  and the references therein), its importance becomes evident when we recognize that such a condition can be used as  an alternative route to bypass a standard ingredient in stellar interiors: the election of certain profiles of the system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Thus, the complexity factor formalism, or, more precisely, its simplified version, namely, when the complexity factor  is zero, allows us to close the system and obtain novel and non-trivial spherically symmetric solutions unknown up  to now.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Thus, the vanishing complexity formalism offers a parallel way to deal with anisotropies in relativistic stars  (see for instance [53, 54]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Now, let us move to the basic details behind the method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The essence of the complexity factor formalism emerges  when we check the orthogonal splitting of the Riemann tensor for static self-gravitating fluids with spherical symmetry  (please, for a detailed explanation, see [51] and also [55]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The (orthogonal) decomposition of the Riemann tensor is  usually tedious labor and was well-studied in the original paper, thus we will avoid repetitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' We will take advantage  of some helpful definitions:  Yαβ = Rαγβδuγuδ,  (23)  Zαβ = R∗  αγβδuγuδ = 1  2ηαγϵµRϵµ  βδuγuδ,  (24)  Xαβ = R∗  αγβδuγuδ = 1  2η  ϵµ  αγ  R∗  ϵµβδuγuδ,  (25)  where the symbol ∗ is the dual tensor, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=',  R∗  αβγδ = 1  2ηϵµγδR  ϵµ  αβ  (26)  and ηϵµγδ is the well-known Levi–Civita tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Utilizing the decomposition of the Riemann tensor, the set of tensors  {Yαβ, Zαβ, Xαβ} can be written in a convenient way, in terms of the physical variables, namely,  Yαβ = 4π  3 (ρ + 3P)hαβ + 4πΠαβ + Eαβ,  (27)  Zαβ = 0,  (28)  Xαβ = 8π  3 ρhαβ + 4πΠαβ − Eαβ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (29)  Also, the tensor Eαβ (defined as Eαβ = Cαγβδuγuδ) can be written as  Eαβ = E  �  sαsβ + 1  3hαβ  �  ,  (30)  5  where E is precisely  E = −e−λ  4  �  ν′′ + ν′2 − λ′ν′  2  − ν′ − λ′  r  + 2(1 − eλ)  r2  �  ,  (31)  satisfying the following properties:  Eα  α = 0,  Eαγ = E(αγ),  Eαγuγ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (32)  At this point it is essential to mention that the tensors {Yαβ, Zαβ, Xαβ} can be expressed in terms of alternative  scalar functions, as was previously discussed in [56].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Now, consider the following tensors: Xαβ and Yαβ in the static  case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Based on that, it is possible to define the so-called structure scalars XT , XT F , YT , YT F , in terms of the physical  variables, as follows:  XT = 8πρ,  (33)  XT F = 4π  r3  � r  0  ˜r3ρ′d˜r,  (34)  YT = 4π(ρ + 3Pr − 2Π),  (35)  YT F = 8πΠ − 4π  r3  � r  0  ˜r3ρ′d˜r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (36)  From Equations (34)–(36), the local anisotropy of pressure is obtained utilizing XT F and YT F with help of the  following relation:  8πΠ = XT F + YT F .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (37)  The vanishing complexity condition, YT F = 0, implies the following relation between the energy density and the  anisotropic factor  Π(r) =  1  2r3  � r  0  ˜r3ρ′(˜r)d˜r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  (38)  Thus, for a given density profile ρ(r), we can compute the anisotropic factor for a self-gravitating system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Notice that  the classical formalism, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', selecting a suitable form of the anisotropic factor by hand (among other alternatives), has  also been significantly investigated over the years (see, for instance, [29, 43, 57–67] and the references therein).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' As the  complexity factor formalism in the context of relativistic stars is so helpful, we will follow this idea and contrast the  results obtained following such an approach with solutions coming from the canonical method, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', taking by hand  the anisotropic factor, for instance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  RESULTS AND DISCUSSION  In the present paper we have investigated within GR anisotropic stars made of quark matter in light of the vanishing  complexity formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In particular, we compute numerically interior solutions of realistic spherical configurations of  anisotropic matter, and we compare our solution against a more conventional approach, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', assuming an ansatz for  the anisotropic factor by hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' For quark matter we adopt the interacting equation-of-state, Pr(ρ), given by [68, 69]  Pr = 1  3 (ρ − 4B) − m2  s  3π  �  ρ − B  a4  + m4  s  12π2  �  1 − 1  a4  + 3 ln  �  8π  3m2s  �  ρ − B  a4  ��  ,  (39)  where Pr is the radial pressure, and ρ is the energy density of homogeneously distributed quark matter (also to  O (m4  s) in the Bag model).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  For the purpose of the present analysis, following Beringer et al [70], we take the  strange quark mass (ms) to be 100 MeV, while the accepted values of the bag constant, B, lie within the range  57 ≤ B ≤ 92 MeV/fm3 [71, 72].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Also, the parameter a4 comes from QCD corrections on the pressure of the quark-free  Fermi sea, and it is directly related with the mass-radius relations of quark stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Note that as far as the EoS is  6  concerned, only the radial pressure is relevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The tangential pressure has already been defined in the Introduction  as well as after Equation (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  After the numerical computations, we display in a number of figures, several quantities of interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In Figures 1–4,  on the x-axis we put the normalized radial coordinate r/R, while on the y-axis we put the quantities of interest,  such as the mass of the star in solar masses, dimensionless quantities (for instance, the relativistic adiabatic index),  and normalized quantities (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', the pressures and the energy density as well as the anisotropic factor in units of the bag  constant, B).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The curves exhibit the usual behaviour observed in interior solutions describing hydrostatic equilibrium.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  In particular, the mass function increases starting from 0 at the centre, while its mass at r = R corresponds to the  star’s mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The energy density and the pressures start from their central value and monotonically decrease until the  radial pressure vanishes at the star’s surface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In contrast, the energy density acquires a surface value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The energy  density and the pressures remain positive throughout the star, while the energy density always remains larger than  the pressures, such that the energy conditions are fulfilled.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Moreover, both sound speeds vary slowly with the radial  coordinate, taking values within the range 0–1 throughout the star, so causality is not violated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The anisotropic factor  turns out to be negative, which is always the case within the vanishing complexity formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Finally, the relativistic  adiabatic index increases monotonically and rapidly acquires large values as we approach the surface of the star.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  At the same time, it always remains larger than the Newtonian value Γ0 = 4/3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In particular, we notice that: (i)  the mass function increase, the anisotropic factor decrease and the energy density and pressures decrease throughout  the star, (ii) the speed of sound, radial and tangential, increase and decrease, respectively, and both are lower than  c2  0 ≡ 1, the relativistic adiabatic index, Γ(r), increase and it is always higher than Γ0 ≡ 4/3, (iii) the corresponding  energy conditions are also satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Thus, in light of the these numerical results, we can confirm that the complexity  factor formalism is a solid approach to obtain well-defined solutions in the context of compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  As a supplementary independent check, we have obtained, numerically again, interior solutions using a more stan-  dard approach, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=', adding external constraints to close the system of differential equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' As a toy model, we have  considered an anisotropic factor, Π(r), as follows [73–77]  Π(r) = κ Pr(r) [1 − e−λ(r)] = κ Pr(r) 2m  r ,  (40)  characterized by a dimensionless parameter, κ, which encodes the strength of the anisotropy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Also, we consider several  values from κ = −1 to κ = −10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='00  r/R  Δ(r)/B  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='0  1  0  1  2  3  4  5  6  r/R  ρ(r)/B  pr(r)/B  pt(r)/B  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 1: Anisotropic SQ stars within the complexity factor: mass function in solar masses (left panel), anisotropic factor  (middle panel), and energy density and pressures (right panel) versus the radial coordinate throughout the star.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Our main results may be summarized as follows: the conventional method predicts more massive objects in com-  parison to the stars within the vanishing complexity formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The mass of the object decreases with the anisotropic  factor, approaching the mass corresponding to the method based on vanishing complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Eventually, causality is  violated as the tangential speed of sound becomes negative, and therefore the solution is no longer realistic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Finally, in Figure (5), we show the mass-to-radius relationship for anisotropic stars for both approaches.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' First  we study anisotropies within the vanishing complexity formalism, and we obtain the curve in red.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Next, when we  consider the conventional method, since now the ansatz for the anisotropic factor is characterized by a continuous  parameter, we can observe the impact of that parameter on the profiles, corresponding to the other 3 curves in the  figure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Increasing the anisotropy, the profile is gradually shifted towards the one corresponding to complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' But at  some point causality is violated, and therefore the solution is not realistic/viable any more.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' That is precisely the  point where we must stop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The last allowed profile remains quite far away from the one obtained within complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Before we conclude our work, a final comment is in order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In the present article our main goal was to study the  implications of the formalism based on vanishing complexity factor, and compare to a more standard approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' It  would be interesting, however, to study the stability of anisotropic stars as well, analyzing radial oscillation modes  7  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='0  r/R  c02  cr2  ct2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='0  0  10  20  30  40  50  60  r/R  Γ(r)  Γ0  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2: Anisotropic SQ stars within the complexity factor: speed of sounds (left panel) and relativistic adiabatic index (right  panel) versus the radial coordinate throughout the star.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The horizontal straight line corresponds to the value Γ0 = 4/3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='9  r/R  (ρ(r) - pr(r) - 2pt(r))/B  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='0  4  5  6  7  8  r/R  (ρ(r) + pr(r) + 2pt(r))/B  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 3:  Anisotropic QS stars within the complexity factor: energy conditions versus the radial coordinate throughout the  star.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='0  r/R  cs2  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 4:  Anisotropic QS stars considering a more standard approach and assuming (i) κ = −1 (dotted red line), (ii) κ = −6  (dashed red line), (iii) κ = −10 (dot-dashed red line), for: mass function in solar masses (left panel), anisotropic factor (middle  panel), and sound speeds (right panel) versus the radial coordinate throughout the star.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' In particular, for the right-hand panel,  we have plotted tangential (red color) and radial (cyan color) c2  s, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' For comparison, we added our solution utilizing  the complexity formalism (solid red line).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  and computing the corresponding frequencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' As this investigation lies beyond the scope of the present work, we  propose to postpone it for the time being, and we hope to be able to do so in the future.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  8  Complexity Method  Conventional Method (κ = -1)  Conventional Method (κ = -3)  Conventional Method (κ = -6)  3  4  5  6  7  8  9  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='4  R(km)  M (M⊙)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 5: Mass-radius profiles obtained by two alternative methods: (i) the vanishing complexity method (solid red line), and (ii)  the conventional method for: κ = −1 (cyan dashed line), κ = −3 (dashed purple line), and κ = −6 (dot-dashed orange line).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  CONCLUSIONS  To summarize our work, in the present article we have obtained interior solutions of strange quark stars made of  anisotropic matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Assuming an interacting equation-of-state, we have taken into account the presence of anisotropies  generated by ultra dense quark matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The anisotropic factor has been introduced employing the formalism based on  the complexity factor, and the structure equations have been integrated numerically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The solutions have been shown to  be well-behaved and realistic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Moreover, we have made a comparison with another more conventional approach, where  the form of the anisotropic factor is introduced by hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Finally, we have obtained the mass-to-radius relationships  within both methods, namely (i) employing the complexity formalism (where there are no free parameters), and (ii)  adopting a certain form for the anisotropic factor (used in previous works, characterized by a free parameter).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Our  results show that as the anisotropy inceases, thus varying the free parameter, the profile is shifted towards the one  corresponding to the complexity factor formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  ACKNOWLEDGMENTS  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' is funded by the Mar´ıa Zambrano contract ZAMBRANO 21-25 (Spain).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' thanks the Funda¸c˜ao para a  Ciˆencia e Tecnologia (FCT), Portugal, for the financial support to the Center for Astrophysics and Gravitation (CEN-  TRA/IST/ULisboa) through the Grant Project No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' UIDB/00099/2020 and Grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' PTDC/FIS-AST/28920/2017.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' M¨uller, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Numerical simulations of the magnetorotational instability in protoneutron stars—I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Influence of  buoyancy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Mon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astron.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2015, 450, 2153–2171.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1093/mnras/stv727.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [10] Kondratyev, V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' R-Process with Magnetized Nuclei at Dynamo-Explosive Supernovae and Neutron Star Mergers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Uni-  verse 2021, 7, 487.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='3390/universe7120487.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [11] Alcock, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Farhi, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Olinto, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Strange stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 1986, 310, 261–272.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1086/164679.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [12] Alcock, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Olinto, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Exotic Phases of Hadronic Matter and their Astrophysical Application.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Ann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  1988, 38, 161–184.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1146/annurev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='ns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='120188.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='001113.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [13] Madsen,  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Physics  and  astrophysics  of  strange  quark  matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Lect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Notes  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  1999,  516,  162–203.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1007/  BFb0107314.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [14] Weber, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Strange quark matter and compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Prog.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Nucl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2005, 54, 193–288.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1016/  j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='ppnp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='07.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='001.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [15] Yue, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Cui, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Xu, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Is psr b0943+10 a low-mass quark star?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2006, 649, L95–L98.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1086/  508421.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [16] Leahy, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Ouyed, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Supernova SN2006gy as a first ever Quark Nova?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Mon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astron.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2008, 387, 1193.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1111/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1365-2966.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2008.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='13312.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [17] Witten, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Cosmic Separation of Phases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 1984, 30, 272–285.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='272.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [18] Farhi, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Jaffe, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Strange Matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 1984, 30, 2379.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [20] Li, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Res.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Typel, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  A new quark-hadron hybrid equation of state  for astrophysics—I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' High-mass twin compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astron.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [23] Yazdizadeh, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The structure of hybrid neutron star in Einstein-λ gravity Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' The Strange star surface: A Crust with nuggets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='041101.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Kulkarni, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rojas, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' An Equation of State for Radiating Dissipative Spheres in General Relativity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' 1992, 193, 201–215.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  Anisotropic  fluids  with  two-perfect-fluid  components.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='1103/  PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Weigert, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Weiss, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  ISBN 9783642303043.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Chowdhury, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Ann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='1016/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Ray, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rahaman, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rubio, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Gravitational decoupled anisotropies in compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Decoupling gravitational sources in general relativity: From perfect to anisotropic fluids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='104019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1140/epjc/s10052-018-5606-6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [46] Sharif,  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Butt,  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Complexity Factor for Charged Spherical System.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' C 2018,  78, 688.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [47] Sharif,  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Butt,  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Complexity factor for static cylindrical system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' C 2018,  78, 850.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [48] Abbas, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Nazar, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Complexity Factor For Anisotropic Source in Non-minimal Coupling Metric f(R) Gravity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' C 2018, 78, 957.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [49] Herrera, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Di Prisco, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Ospino, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Complexity factors for axially symmetric static sources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 2019,  99, 044049.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [50] Prasad, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Kumar, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Anisotropic relativistic fluid spheres with a linear equation of state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' New Astron.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2022, 95, 101815.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='1016/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='newast.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [51] Herrera, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' New definition of complexity for self-gravitating fluid distributions: The spherically symmetric, static case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 2018, 97, 044010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='044010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [52] Sanudo,  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Pacheco,  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Complexity  and  white-dwarf  structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='physleta.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2009.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='01.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='008.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Contreras, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Fuenmayor, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Ramos, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Anisotropic star models in the context of vanishing complexity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Ann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2022, 436, 168671.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1016/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='aop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [54] Andrade, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Contreras, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Stellar models with like-Tolman IV complexity factor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [55] Gomez-Lobo, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Dynamical laws of superenergy in General Relativity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Quant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [56] Herrera,  L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  Ospino,  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Di  Prisco,  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Fuenmayor,  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Troconis,  O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Structure  and  evolution  of  self-  gravitating  objects and the orthogonal  splitting  of the  Riemann  tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 2009,  79, 064025.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='064025.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [57] Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lopes, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Millisecond pulsars modeled as strange quark stars admixed with condensed dark matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Mod.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1142/S0218271818500931.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [58] Moraes, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Lopes, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Anisotropic Dark Matter Stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='084023.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [59] Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Anisotropic strange quark stars with a non-linear equation-of-state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1140/epjp/i2019-12842-4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Lopes, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='1140/epjc/s10052-020-7900-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Tello-Ortiz, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Gomez-Leyton, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Study on anisotropic stars in the framework of Rastall gravity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Space Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lopes, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Radial oscillations and tidal Love numbers of dark energy stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Plus 2020, 135, 856.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1140/epjp/s13360-020-00867-x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [66] Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lopes, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Interior solutions of relativistic stars with anisotropic matter in scale-dependent  11  gravity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Eur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' C 2021, 81, 63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1140/epjc/s10052-021-08881-8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [67] Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rinc´on, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lopes, I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Slowly rotating dark energy stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Dark Univ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2021, 34, 100885.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1016/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='dark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='100885.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [68] Becerra-Vergara, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Mojica, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lora-Clavijo, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Cruz-Osorio, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Anisotropic Quark Stars with an Interacting Quark  Equation of State.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 2019, 100, 103006.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='100.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='103006.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [69] Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Tangphati, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Banerjee, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Electrically charged compact stars with an interacting quark equation of  state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Chin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2022, 77, 1682–1690.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1016/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='cjph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='027.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [70] Beringer, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Arguin, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Barnett, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Copic, K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Dahl, O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Groom, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lin, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Lys, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Murayama, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Wohl, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Review of Particle Physics (RPP).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' D 2012, 86, 010001.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1103/PhysRevD.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='010001.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [71] Fiorella Burgio, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Fantina, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Nuclear Equation of state for Compact Stars and Supernovae.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Space Sci.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  Libr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' 2018, 457, 255–335.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='1007/978-3-319-97616-7 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content='  [72] Blaschke, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Chamel, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Phases of dense matter in compact stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
+page_content=' Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content='  [77] Arba˜nil, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+page_content=' Panotopoulos, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/R9FRT4oBgHgl3EQf8jhZ/content/2301.13684v1.pdf'}
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+COFIBRANT INDECOMPOSABLES IN CHAIN COMPLEX VALUED TAME
+FUNCTORS INDEXED BY DIMENSION ONE POSETS
+WOJCIECH CHACH´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+Abstract. In this work, we provide a model structure on full subcategories of tame objects in
+functor categories indexed by continuous realizations of posets of dimension 1. We also char-
+acterize the indecomposable cofibrant objects when the landing category is the one of bounded
+non-negative chain complexes. In addition, we present a general method to construct indecom-
+posables in a functor category by a gluing technique.
+1. Introduction
+In this article, we study the category of tame functors indexed by a poset Q and with values
+in the category of bounded non-negative chain complexes of vector spaces. We give conditions on
+the poset Q under which this category has the projective model structure, and provide a structure
+theorem for its cofibrant objects. The motivation comes from persistence theory.
+Persistence theory is a discipline at the intersection of mathematics, computer science, and data
+analysis. Its key feature is being able to avoid cherry-picking parameters in data analysis, studying
+instead how the (topological) features evolve as the parameters change. Thus objects arising in
+persistence theory are indexed by a finite set of values, which however changes continuously from
+one object to the other. Therefore, the natural language to treat them is the one of tame functor
+categories, and the goal is to obtain computable invariants for these categories. In this work, we
+focus on the theoretical backbone of persistence theory, in particular broadening the class of usable
+indexing posets.
+We study functor categories whose indexing posets have dimension 1 (Section 2.1). Intuitively,
+this means that between any two comparable elements, there is only one monotone path. This
+ensures that there are well-behaved transformations from a finite poset to its continuous realization
+and vice versa (Section 2.2). This way, it is possible to define tame functor categories where, even
+if the parameters are allowed to vary continuously, the information is always condensed in a finite
+set of their values, providing a middle ground between generality and practicality.
+Indecomposables are a classical source for invariants, and thus understanding their behavior in
+our categories of interest is essential. In Section 3, we present a method to construct indecom-
+posables in any functor category landing in an abelian category. The idea is to “glue” together
+objects with different indexing posets, such that one object is indecomposable and the other satisfies
+certain conditions. Thus, one can start with a simple object, whose indecomposability is obvious,
+and build more and more complex indecomposables by expanding the underlying poset using con-
+ditions that are easier to verify than the indecomposability of the full object. We will use this
+technique to show that some of our following results about indecomposables intrinsically require
+functors to be parametrized by posets of dimension 1. Without this assumption, it is possible to
+build indecomposables that are arbitrarily complicated.
+1
+arXiv:2301.04079v1  [math.AT]  10 Jan 2023
+
+2
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+The assumption that Q, if not finite, is the continuous realization [3] of a finite poset of dimension
+1 also ensures the existence of the projective model structure on Tame(Q, M). This is the full
+subcategory of Fun(Q, M), where M is a model category, whose objects are functors which can
+be expressed as the left Kan extensions along some finite subposet inclusion, D ⊂ Q (Section 4).
+When the indexing poset is finite, the existence of such a model structure is a well-known fact [4],
+but it is no longer guaranteed when the indexing poset is not finite. We thus expand the class of
+continuous posets for which Tame(Q, M) admits a model structure. We are especially interested
+in the case when M is ch, the category of bounded and non-negative chain complexes of vector
+spaces, since parametrized chain complexes are part of the persistence pipeline (see also [6]).
+In general, Tame(Q, ch) is of wild representation type, which means that finding a compact
+description of the indecomposables is not feasible, so we cannot use them to define invariants
+directly. However, we can make use of the projective model structure: the latter provides a wealth
+of ways to define invariants, for example via cofibrant approximations. Therefore, we concentrate
+on cofibrant objects of Tame(Q, ch). Cofibrant objects are characterized by being free degree-wise.
+We prove that, if the indexing poset has dimension 1, then the indecomposable cofibrant objects are
+nonzero only in at most two consecutive degrees. This property allows us to prove one of our main
+contribution: a structure theorem for cofibrant objects in Tame(Q, ch), when Q is the realization
+of a finite poset of dimension 1. More precisely, we show that all indecomposable cofibrant objects
+in Tame(Q, ch) are suspensions of two types of indecomposables. One type consists of the cones of
+rank 1 free objects in Tame(Q, vectF), and the other consists of minimal covers of indecomposable
+objects there. Therefore, we can approximate any object in Tame(Q, ch) with an object that is no
+more complicated to describe than an object in Tame(Q, vectF) but it carries more information.
+In conclusion, we (1) prove the existence of the projective model structure on Tame(Q, M),
+where M is a model category and Q is the continuous realization of a finite poset of dimension
+1, (2) provide a technique to construct indecomposables in functor categories landing in abelian
+categories, and (3) show a structure theorem for cofibrant objects in Tame(Q, ch), with Q as above.
+2. Preliminary results
+The extraction of invariants from compact geometric objects, common in topological data anal-
+ysis, gives rise to compact representations of posets in a certain category C. We call these represen-
+tations of posets tame functors. They are defined as left Kan extensions along poset functors from
+a finite poset, which encode the relevant changes of the underlying geometric objects.
+Definition 2.1. Let Q be a poset and C a category. A functor X : Q → C is called tame if there is
+a functor α: D → Q from a finite poset D, and a functor Y : D → C such that X ∼= αKY , where αK
+denotes the left Kan extension along α. The poset functor α: D → Q is called a discretization of
+X. We denote by Tame (Q, C) the full subcategory given by all tame objects of Fun (Q, C).
+If Q in the above definition is finite, then Tame(Q, C) and Fun(Q, C) coincide.
+If C is ch,
+the category of bounded chain complexes over a field, we call X an object in Tame(Q, ch) a
+(tame) parametrized chain complex, often omitting “tame” for simplicity, or a chain complex
+indexed by Q.
+To the end of endowing the category of tame functors Tame(Q, M), where M is a model category
+itself, with a model structure, which is the goal of Section 4, it is important that tame functors
+admit all finite limits and colimits. As for colimits, this is a consequence of left Kan extensions
+being left adjoints. In order to guarantee that limits are also preserved when we take left Kan
+extensions, we will consider transfers as a way to take a tame functor defined on an infinite poset
+
+COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE
+3
+to a functor defined on a finite poset. The transfer construction requires additional assumptions
+on posets: the existence of a transfer is ensured for posets obtained as realizations of posets of
+dimension 1.
+2.1. Posets of dimension 1 and realizations. Let Q be a poset. Given two elements p, x ∈ Q,
+p is a parent of x if p < x and there exists no y ∈ Q such that p < y < x. The collection of parents
+of x is denoted by P(x). Let S be a subposet of Q. An element a ∈ Q is an ancestor of S if a ≤ x
+for all x ∈ S. Note that if S = {x}, then P(x) is a subset of ancestors of x. If y ≤ x for every y
+in S and there is no z in Q such that y ≤ z < x for every y in S, then x is a sup of S. If S has
+a unique sup x, then this is called the coproduct (or join) of S, and it is denoted by � S. If I is
+a poset and S is a set, the collection of functions f : S → I is denoted by IS and forms a poset:
+f ≤ g in IS if and only if f(x) ≤ g(x), for every x in S. We use the symbol dom(f) to denote the
+domain of f. Consider a subposet Q′ ⊆ Q and an element x in Q. The subposet Q′ ≤ x (resp.
+Q′ < x) is defined as the intersection Q′ ∩ {y ∈ Q | y ≤ x} (resp. Q′ ∩ {y ∈ Q | y < x}).
+Definition 2.2. Let Q be a poset and x ∈ Q. We say that x has dimension 1 in Q, denoted by
+dimQ(x) = 1, if Q < x is not empty and x is not a sup of a 2-element subset of Q < x with an
+ancestor. We say that x has dimension 0 if Q < x is empty. A poset Q has dimension 1, denoted
+by dim(Q) = 1, if dimQ(x) ≤ 1 for all x ∈ Q.
+Examples of posets of dimension 1 include N and R. R2 and the posets in Figure 4 are examples
+of posets of dimension strictly greater than 1 (see [3, Paragraph 3.1] for a definition of posets of
+general dimension).
+Definition 2.3. Let Q be a poset of dimension 1. Its realization, denoted by R(Q), is the disjoint
+union �
+x∈Q
+�
+S⊆P(x)(−1, 0)S such that S is either empty or has cardinality 1.
+For each x ∈ Q, we identify the subset �
+S⊆P(x),|S|=0(−1, 0)S = (−1, 0)∅ with (x, 0), and the
+subset �
+S⊆P(x),|S|=1(−1, 0)S = �
+{p}⊆P(x)(−1, 0){p} with {(x, f) | and f : {p} → (−1, 0)}. For
+simplicity, we refer to an element of R(Q) as a pair (x, f). Intuitively, the realization of a poset of
+dimension 1 is a continuous set, where the “gaps” between elements of the original poset are filled
+by edges parametrized by (−1, 0).
+The realization of a poset is not just a set, but a poset.
+Given (x, f) and (y, g) in R(Q),
+(y, g) ≤ (x, f) when one of the following conditions holds:
+• (x, f) = (x, 0) and y ≤ x,
+• y = x, dom(g) = dom(f) = p, and g(p) ≤ f(p),
+• y < x and y ≤ dom(f).
+We observe that Q can be identified with the subposet {(x, 0)}x∈Q of R(Q).
+Proposition 2.4. The realization of a poset of dimension 1 is a poset of dimension 1.
+Proof. By a case analysis, one can show that the relation on R(Q) is reflexive, antisymmetric,
+and transitive. It remains to show that R(Q) has dimension 1. Fix x ∈ Q. If dimQ(x) = 0,
+then by construction also dimR(Q)(x, 0) = 0.
+If dimQ(x) = 1, then for every (x, f) in R(Q)
+we have two cases.
+If dom(f) = ∅, then there exists y < x because dimQ(x) = 1, and hence
+(y, 0) < (x, 0) = (x, f); if dom(f) ̸= ∅, then (y, 0) < (x, f), for y = dom(f). From this we conclude
+that R(Q) < (x, f) is not empty for every x such that dimQ(x) = 1.
+Let us assume now by
+contradiction that there is a (x, f) in R(Q) that is the sup of (y, g), (z, h) < (x, f) with a common
+ancestor (a, l).
+We observe that necessarily (x, f) = (x, 0).
+Assume that dom(g) and dom(h)
+
+4
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+are non-empty. Then, since (x, f) is a sup of (y, g) and (z, h), and Q has dimension 1, dom(g)
+and dom(h) are not comparable. This, together with the fact that (a, l) ≤ (y, g), (z, h), implies
+that a < dom(g), dom(h) < x, which contradicts that Q has dimension 1. If (y, g) = (y, 0) and
+dom(h) ̸= ∅, then a < y, dom(h) < x, which again contradicts Q being of dimension 1. The cases
+(z, h) = (z, 0) and dom(g) ̸= ∅, and (y, g) = (y, 0), (z, h) = (z, 0) are analogous.
+□
+Example 2.5. Consider the poset N. Then R(N) is isomorphic to the real interval [0, ∞). Indeed,
+the map R(N) → [0, ∞) that sends (x, 0) to x in N, and (x, f : {p} → (−1, 0)) to x + f(p), if x > 0,
+is an isomorphism of posets.
+Definition 2.6. Let Q be a finite poset of dimension 1 and R(Q) its realization. Consider a finite
+subset V ⊂ (−1, 0) and define the subposet R(Q, V ) of R(Q) as R(Q, V ) := {(x, f) ∈ R(Q) |
+f(dom(f)) ⊆ V or (x, f) = (x, 0)}.
+We note that since Q is finite, R(Q, V ) is also finite. An example is shown in Figure 1.
+•
+•
+•
+•
+•
+i
+i
+i
+i
+•
+•
+•
+•
+•
+•
+•
+•
+Figure 1. From left to right: a poset Q of dimension 1, R(Q, V ) with V = { 1
+4, 3
+4},
+and the realization R(Q). In each poset, arrows point to greater elements.
+2.2. Back and forth with transfer and left Kan extensions. We recall that a functor X : D →
+C, where D is any poset and C is closed under finite colimits, can be extended as a left Kan extension
+along an inclusion i: D ⊆ Q, so to obtain a new functor iKX : Q → C. The left Kan extension
+is a functor iK : Fun(D, C) → Fun(Q, C) left adjoint to the pre-composition by i.
+As such, it
+commutes with colimits in Fun(Q, C). However, it may fail to commute with limits. In order for
+that commutativity to happen, we need additional hypotheses on the poset. In [3], the authors
+showed that left Kan extensions preserve limits if the indexing poset is an upper semilattice. Our
+first aim is to extend the class of posets for which this holds by proving an analogous result for
+functors indexed by realizations of posets of dimension 1.
+The idea for the proof is the following: first, we show that in the realization of a poset of
+dimension 1 each downset, intersected with a certain subposet of the realization, admits a unique
+sup, even if these posets are, in general, not upper semilattice. This is the key observation, as it
+ensures that transfers are well defined (Definition 2.8). Using then the techniques of [3], we obtain
+that the transfer is left adjoint to the inclusion of posets. Therefore, the precomposition with the
+transfer is isomorphic to the left Kan extension, providing an explicit description of the latter.
+Proposition 2.7. Let Q be a poset of dimension 1 and V a finite subset of R(Q). For every (x, f)
+in R(Q), the coproduct �(R(Q, V ) ≤ (x, f)) exists in R(Q, V ). Explicitly,
+(1)
+�
+(R(Q, V ) ≤ (x, f)) =
+�
+(x, dom(f) �→ max Z(f))
+if Z(f) ̸= ∅,
+(p, 0)
+if Z(f) = ∅.
+where Z(f) = {v ∈ V | f(dom(f)) ≥ v}.
+
+COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE
+5
+Proof. Fix (x, f) ∈ R(Q). If (x, f) ∈ R(Q, V ), then �(R(Q, V ) ≤ (x, f)) = (x, f), and the claim is
+true. So, assume that (x, f) ̸∈ R(Q, V ). Since R(Q, V ) contains all elements of the form (x, 0), we
+necessarily have that x is in Q and there exists a unique y = dom(f) in P(x) for which f(y) ̸= 0.
+The subposet {(z, g) ∈ R(Q, V )) | (y, 0) ≤ (z, g) < (x, f)} is finite and totally ordered. Thus,
+it admits a coproduct. This coproduct is either (y, 0), if f(y) < min V , or (x, f ′), where f ′(y) =
+max{v ∈ V | f(y) ≥ v}. According to the partial order in R(Q), every element in R(Q, V ) ≤ (x, f)
+is less than or equal to the coproduct of {(z, g) ∈ R(Q, V )) | (y, 0) ≤ (z, g) < (x, f)}, meaning that
+the coproduct of the latter coincides with the coproduct of R(Q, V ) ≤ (x, f).
+□
+Proposition 2.7 ensures that the following notion of transfer is well defined whenever Q is of
+dimension 1.
+Definition 2.8. Let Q be a poset of dimension 1 and consider the inclusion i: R(Q, V ) �→ R(Q).
+The function i! : R(Q) → R(Q, V ) defined as i!(x, f) = �(R(Q, V ) ≤ (x, f)) is called the transfer
+of i.
+Figure 2. The poset R(Q, V ) shown inside the poset R(Q), with R(Q, V ) and
+R(Q) taken as in Figure 1. The colored points (x, f) and (x, g) belong to R(Q),
+and the corresponding arrows show the transfer applied to these points.
+In plain words, pre-composition with the transfer allows for going from the continuous indexing
+poset R(Q) back to a discretization R(Q, V ) of it using a finite subset V of (−1, 0). The following
+remark makes this description, illustrated in Figure 2, rigorous.
+Remark 2.9. For every (x, f) ∈ R(Q), we have the following (in)equalities:
+(1) i!i(x, f) = (x, f) ∈ R(Q, V ),
+(2) ii!(x, f) ≤ (x, f) ∈ R(Q).
+Following the tameness Definition 2.1, we consider tame functors parametrized by the continuous
+poset R(Q), with Q a poset of dimension 1, as the left Kan extension of a finite discretization
+R(Q, V ). As such, a tame functor indexed by the realization of a finite poset of dimension 1 is
+constant between an element and its parent. On the other hand, the transfer allows us to condense
+the locally constant information encoded by tame functors into nodal points where the functor takes
+different values.
+Proposition 2.10. The functor (−)i! : Fun(R(Q), C) → Fun(R(Q, V ), C) is left adjoint to the
+functor (−)i : Fun(R(Q, V ), C) → Fun(R(Q), C).
+The proof follows by the same arguments of [3, Proposition 7.4], which can be applied in our
+setting by Definition 2.8 and Remark 2.9.(1) and .(2).
+Since both (−)i! and iK are left adjoint to (−)i, we obtain the following result.
+
+i(α, 0) = (c, 0)
+(c, f)
+i(α,f)
+(c, g)
+i(c,g)6
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+Corollary 2.11. Let Q be a poset of dimension 1 and V a finite subset of (−1, 0). For every
+(x, f) ∈ R(Q, V ) and X ∈ Fun(R(Q, V ), C), iKX(x, f) ∼= Xi!(x, f).
+As above mentioned, the left Kan extension iK along the inclusion i: R(Q, V ) �→ R(Q) com-
+mutes with colimits. We now prove that it also commutes with limits. For this to be true, it is
+crucial that Q is a poset of dimension 1 because we use the transfer.
+Lemma 2.12. Let C be a category closed under finite (co)limits, Q a poset of dimension 1, V a
+finite subposet of (−1, 0), and consider the inclusion i: R(Q, V ) �→ R(Q). The left Kan extension
+iK : Fun (R(Q, V ), C) → Fun (R(Q), C) commutes with finite (co)limits.
+Proof. Since left adjoints commute with colimits, we just need to show that iK commutes with
+limits.
+Corollary 2.11 guarantees that, for X in Fun(R(Q, V ), C), iKX(x, f) is isomorphic to
+Xi!(x, f) = X (� (R(Q, V ) ≤ (x, f))). Let φ: D → Fun(R(Q, V ), C)) be a functor from a finite
+category. The limit limD φ belongs to Fun(R(Q, V ), C) and, for every (x, f) ∈ R(Q), we have that
+iK( limD φ)(x, f) ∼= ( limD φ)i!(x, f) = limD(φ(−)(i!(x, f))) ∼= limD(iKφ)(x, f)
+where the first and last isomorphisms hold by Corollary 2.11.
+□
+The last two results of this section allow us to restrict to the full subcategory of tame functors,
+which is necessary to define a model structure (see Section 4).
+Lemma 2.13. Let Q be a poset of dimension 1. A functor X in Tame(R(Q), C) admits a dis-
+cretization of the form i: R(Q, V ) �→ R(Q).
+Proof. Since X is tame, there exist functors α: D → R(Q), with D a finite poset, and Y : D → C
+such that X ∼= αKY . Considering R(Q, V ), with V = {f(dom(f)) | (x, f) ∈ α(D)}, we have
+α(D) ⊆ R(Q, V ). Since left Kan extensions commute with compositions, we have X ∼= αKY ∼=
+(iα)KY = iK(αKY ), where i is the inclusion R(Q, V ) ⊂ R(Q). Thus, since R(Q, V ) is finite, X is
+discretized by i.
+□
+Proposition 2.14. In addition to the assumptions in Lemma 2.12, assume that Q is finite, and
+let φ: D → Fun(R(Q), C) be a functor from a finite category. If φ(d) is tame for every object d in
+D, then limD φ is also tame.
+Proof. For every d in D, let id : R(Q, Vd) �→ R(Q), with Vd finite, be a discretising inclusion for
+φ(d), which exists by Lemma 2.13. Then i: R(Q, � Vd) �→ R(Q) discretises each φ(d). Moreover,
+by Remark 2.9, the natural transformation φ(d) → iK(φ(d)i), adjoint to the identity φ(d)i → φ(d)i,
+is an isomorphism, for every d. Consequently, limD φ is isomorphic to limD iK(φi), which is also
+isomorphic to iK(limD φi), by Lemma 2.12. Hence, we have shown that limD φ is isomorphic to the
+left Kan extension along i, implying that it is tame.
+□
+3. Generating indecomposables by gluing
+In this section, we exhibit a general method to construct indecomposables in a functor category.
+In particular, we give conditions under which it is possible to extend the indexing poset of an
+indecomposable by gluing another object to it while preserving indecomposability.
+We first recall the following well-known result [1, Pag. 18]:
+Lemma 3.1. X : Q → C is indecomposable if and only if End(X) does not contain any non-trivial
+idempotent elements.
+
+COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE
+7
+Let now Q be any poset and X : Q → C be a functor with C an Abelian category. Let A and B
+be subposets of Q such that Q = A ∪ B. Denote by XA, XB and XA∩B the restrictions of X to
+A, B and A ∩ B, respectively.
+Lemma 3.2. If XA is indecomposable and the morphism End(XB) → End(XA∩B), defined by the
+restriction, is a monomorphism, then X is indecomposable.
+Proof. By Lemma 3.1, we aim to show that End(X) contains only 0 and idX as idempotent elements.
+Consider the maps End(XA) → End(XA∩B) ←� End(XB) induced by the restrictions, the right one
+being a monomorphism by hypothesis. They fit into the following diagram where P is their pullback:
+End(X)
+P
+End(XB)
+End(XA)
+End(XA∩B)
+β
+γ
+α
+By a property of pullbacks, P → End(XA) is also a monomorphism. Since P is isomorphic to
+{(ϕ, ψ) ∈ End(XA) ⊕ End(XB) | ϕ|A∩B = ψ|A∩B} and α and β are induced by the restrictions
+of X to A and B, respectively, the morphism γ is a monomorphism, which implies that α is also
+a monomorphism. Since α is induced by the restriction of X to A, it sends idempotent elements
+of End(X) to idempotent elements of End(XA). In particular, if ϕ is an idempotent element of
+End(X), then γϕ = ϕ|A is also idempotent in End(XA). By indecomposability of XA, ϕ|A can
+either be 0 or idX|A, and then, since γ is a monomorphism, ϕ must be either 0 or idX.
+□
+Our goal is now to determine under which circumstances End(XB) includes into End(XA∩B).
+Lemma 3.3. Given the diagram
+(2)
+Y
+X
+Y
+X
+β
+η
+ν
+β
+,
+there exists at most one ν making the diagram commute if, and only if, hom (coker β, X) = 0.
+Proof. Consider the following right exact sequence: Y
+β−→ X ↠ coker β. By applying hom(−, X)
+and hom(−, Y ) to it, we obtain the following commutative diagram:
+hom(Y, X)
+hom(X, X)
+hom(coker β, X)
+0
+hom(Y, Y )
+hom(X, Y )
+hom(coker β, Y )
+0
+β∗
+.
+The condition hom(coker β, X) = 0 is equivalent to β∗ being a monomorphism. Let us take ξ ∈
+hom(Y, X) to be the image of η ∈ hom(Y, Y ) along the leftmost vertical map. The preimage of ξ
+under β∗ is either empty or exactly one morphism ν.
+□
+Theorem 3.4. Let A and B be subposets of Q such that Q = A∪B. Let X : Q → C be a functor and
+let β : iKXA∩B → XB be the unique morphism given by the universality of the left Kan extension
+
+8
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+along the inclusion i: A ∩ B → B. If hom(coker β, XB) = 0 and XA is indecomposable, then X is
+indecomposable.
+Proof. We need to show that the morphism End(XB) �→ End(XA∩B). By Lemma 3.2, this, together
+with the assumption that XA is indecomposable, implies that X is indecomposable. Assume that
+there are two endomorphisms of XB, ν and ν′, such that their restrictions to A ∩ B coincide. The
+endomorphism η induced by their left Kan extension along the inclusion of A ∩ B into B fits into
+the following diagram:
+(3)
+iKXA∩B
+XB
+iKXA∩B
+XB
+β
+η
+ν
+ν′
+β
+.
+Thus, by Lemma 3.3, ν = ν′.
+□
+Next, we exemplify how to construct complex indecomposables using this technique. This ex-
+ample also shows that Theorem 5.14 does not hold if the dimension of the indexing poset is not 1
+(see Section 5.3).
+F
+F2
+F
+F
+F
+F
+F
+F
+F3
+F
+F
+F3
+F
+F
+F
+F
+F
+F
+F
+F
+F
+F
+F
+�
+0
+1
+�
+�
+1
+0
+�
+�
+�
+0
+1
+0
+�
+�
+�
+1
+0
+�
+�
+1
+1
+�
+�
+�
+0
+1
+0
+�
+�
+�
+�
+1
+0
+0
+�
+�
+�
+1
+0
+0�
+�
+1
+0
+0�
+�
+�
+0
+0
+1
+�
+�
+�
+�
+1
+1
+1
+�
+�
+�
+�
+0
+0
+1
+�
+�
+Figure 3. A parametrized chain complex X (for its indexing poset see Figure 4c).
+Only its non-trivial maps are displayed and they are given by the identity if not
+otherwise specified. Vertical maps are all chain maps.
+Corollary 3.5. The object X in Fun(Q, ch) defined as shown in Figure 3 is indecomposable.
+Proof. The proof follows by repeatedly applying Theorem 3.4 to the restrictions of X to the series
+of posets depicted in Figure 4, since XA is step (A) is clearly indecomposable. Indeed, in all three
+steps, iKXA∩B is nonzero in fewer degrees than XB (precisely, nonzero only in degree 0 in step
+
+COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE
+9
+(A), 0 and 1 in step (B), and 1 in step (C)). Therefore, coker β is zero in the same degrees. So, by
+commutativity, the only possible morphism between coker β and XB is the zero morphism.
+□
+A
+B
+(a)
+A
+B
+(b)
+A
+B
+(c)
+Figure 4. Posets used to construct the indecomposable object shown in Figure 3.
+4. Model categories indexed by posets
+In this section we show that it is possible to endow the category Tame(R(Q), M) with a model
+structure whenever M is a model category itself and Q is a poset of dimension 1. Because R(Q)
+is not a finite poset, this is an advancement with respect to the known result for finite posets [4],
+which we will briefly recall for the reader’s convenience. It is also a new result with respect to [2]
+and [3], where the indexing poset is required to be [0, ∞) and an upper semilattice, respectively.
+Definition 4.1 ([4]). Let Q be a finite poset and M a model category.
+In Tame (Q, M) we
+define weak equivalences and fibrations pointwisely.
+Moreover, a morphism ϕ: X → Y in
+Tame (Q, M) is said to be a cofibration if, for every x ∈ Q, the mediating morphism
+ˆϕx : colim (colimQ<x Y ← colimQ<x X → X(x)) → Y (x)
+in the pushout diagram
+(4)
+colimQ<x X
+X(x)
+colimQ<x Y
+P
+Y (x)
+colimQ<x ϕ
+ˆϕx
+is a cofibration in M.
+As weak equivalences and fibrations are defined pointwisely, the above-defined structure is usu-
+ally referred to as a projective model structure. We now extend this model structure to the
+continuous case given by tame functors indexed by realizations of finite posets of dimension 1.
+Definition 4.2. Given a model category M and a finite poset Q of dimension 1, a morphism
+ϕ: X → Y in Tame (R(Q), M) is said to be a
+- weak equivalence if ϕ(x, f) is a weak equivalence in M for all (x, f) ∈ R(Q);
+- fibration if ϕ(x, f) is a fibration in M for all (x, f) ∈ R(Q);
+
+10
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+- cofibration if there is a finite set V ⊆ (−1, 0] with an inclusion i: R(Q, V ) �→ R(Q) dis-
+cretising both X and Y , such that iKϕ: iKX → iKY is a cofibration in Tame (R(Q, V ), M).
+Note that, in the definition of a cofibration, the existence of a common discretisation is guaranteed
+by [3, Prop. 8.3].
+Proposition 4.3. Let M be a model category, Q a finite poset of dimension 1, and i: R(Q, V ) �→
+R(Q) a poset inclusion. If a morphism ϕ: F → G in Fun(R(Q, V ), M) is a weak equivalence (resp.
+a fibration), then so is its left Kan extension iKϕ: iKF → iKG in Fun(R(Q), M).
+Proof. Thanks to Proposition 2.7, we can apply the same arguments of [3, Prop. 9.4].
+□
+Theorem 4.4. Assume that Q is a finite poset of dimension 1. With the choices of fibrations,
+cofibrations, and weak equivalences as in Definition 4.2, Tame (R(Q), M) is a model category.
+Proof. The first axiom of a model category is satisfied by Lemma 2.12. The rest of the proof follows
+from the same arguments of [3, Th. 9.3], using Remark 2.9, Corollary 2.11 and Proposition 4.3 to
+obtain the same guarantees given by upper semilattices in [3].
+□
+In what follows, we overload the symbol Tame(R(Q), ch) to denote the model category given by
+Definition 4.2. A model structure allows for the following notion.
+Definition 4.5. An object X in a model category is cofibrant if the unique morphism from the
+initial object of the category to X is a cofibration.
+Cofibrant objects are interesting at a theoretical level since, by the factorization axiom, any
+object X in a model category can be “approximated” by its cofibrant replacement, i.e.
+a
+cofibrant object that maps to X as a fibration and a weak equivalence. Usually cofibrant objects
+have more properties than general objects and thus are easier to handle. In computation, they
+provide a wealth of invariants (see [2]) such as the minimal cover (discussed in Section 5.2).
+5. Chain complexes parametrized by posets of dim 1
+In this section we particularize the model structure introduced in Section 4 by taking M to be the
+category of bounded chain complexes, ch, with its standard model structure [4]. We provide insight
+into the structure of cofibrant objects and, particularly, into cofibrant indecomposables. While some
+results in Sections 5.1 and 5.2 can be generalized to other settings in which Tame(Q, ch) admits a
+projective model structure without Q being of dimension 1, the results presented in Section 5.3 are
+strongly dependent on the fact that the indexing poset is of dimension 1.
+The restriction of an object X in Tame (Q, ch) to a fixed degree n ∈ N is denoted by Xn, and
+it can be seen as an object in Tame (Q, vectF). We denote the parametrized chain maps of X by
+∂n : Xn → Xn−1.
+Definition 5.1. An object X in Tame(Q, ch) is said to be nonzero in (at most) two consec-
+utive degrees if there exists i ∈ N such that Xj = 0 if j ̸= i, i + 1. It is said to be acyclic if
+HnX ∼= 0 for every n ∈ N.
+For example, X = 0 is nonzero in two consecutive degrees (for any choice of i ∈ N) and acyclic.
+
+COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE
+11
+5.1. Cofibrancy and freeness. We show that the notion of cofibrancy in Tame (R(Q), ch) is
+strongly related to that of freeness in the category Tame (R(Q), vectF). This result is fundamental
+in view of Theorem 5.14 to characterize cofibrant indecomposables in the category Tame(R(Q), ch).
+For any poset Q, we say a functor in Tame (Q, vectF) to be a parametrized vector space.
+Such an object is free if it is isomorphic to ⊕x∈SF[x, −) for some finite S ⊆ Q, where, for every
+y ≤ y′,
+F[x, y) =
+�
+F
+if x ≤ y
+0
+otherwise
+,
+F[x, y) → F[x, y′) =
+�
+idF
+if x ≤ y ≤ y′
+0
+otherwise
+.
+Lemma 5.2. Let Q be a finite poset of dimension 1. An object X in Tame (R(Q), ch) is cofibrant
+if and only if, for all n ∈ N, Xn is free in Tame (R(Q), vectF).
+Proof. For (x, f) ∈ R(Q), let us consider the mediating morphism ˆϕ(x,f) : P → X(x, f) whose
+domain is the pushout P := colim
+�
+colimR(Q)<(x,f) ← 0 → 0
+�
+. By Definitions 4.2 and 4.5, X is
+cofibrant if and only if ˆϕ(x,f) is a monomorphism for every (x, f) ∈ R(Q). A direct computation
+shows that ˆϕ(x,f) is a monomorphism if and only if X is free in each degree, giving the claim.
+□
+5.2. Minimality. We decline the concept of minimality in the model category Tame(R(Q), ch)
+and in Tame(R(Q), vectF), with the goal of defining invariants. We first prove the existence of
+minimal covers in Tame(R(Q), ch). Then we show some of their properties and those of minimal
+resolutions in Tame(R(Q), vectF), in particular with regard to indecomposable objects. To ensure
+that Tame(R(Q), ch) is a model category, we assume Q to be a finite poset of dimension 1.
+Definition 5.3. Let Q be a finite poset of dimension 1. The minimal cover of an object X
+in Tame(R(Q), ch) is a morphism π: C → X that is a weak equivalence and a fibration, with C
+cofibrant, and such that any endomorphism φ: C → C that satisfies π = π ◦ φ is an isomorphism.
+The minimal cover is a particular cofibrant approximation that needs not exist in any model
+category but it is unique if it does, thus providing an invariant (see [2] for a general description).
+Proposition 5.4. Let Q be a finite poset of dimension 1. A morphism π: C → X in Tame(R(Q), ch)
+is a minimal cover if and only C is cofibrant, π is a fibration and a weak equivalence, and no acyclic
+direct summand of C is in the kernel of π.
+Proof. Follows by arguments analogous to those of [2, Prop. 5.1], since Tame(R(Q), ch) is a Krull-
+Schmidt category.
+□
+Corollary 5.5. Let Q be a finite poset of dimension 1. Every object X in Tame(R(Q), ch) admits
+a minimal cover.
+Proof. For every object X in Tame(R(Q), ch), let us consider its cofibrant replacement p: C′ → X.
+Since Tame(R(Q), ch) is a Krull-Schmidt category, we can decompose C′ into indecomposables and
+remove all the acyclic indecomposable summands that are sent to zero via p. The resulting map is
+a minimal cover by Proposition 5.4.
+□
+Lemma 5.6. Let Q be a finite poset of dimension 1, X an object in Tame(R(Q), ch) and C
+π
+−−−↠ X
+its minimal cover. If C is indecomposable, then X is indecomposable.
+
+12
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+Proof. By arguing as in [5, Prop. 5.21], we see that the minimal cover preserves direct sums. Thus,
+if X ∼= X1 ⊕ X2, then the minimal cover C of X decomposes into the sum of the minimal covers of
+X1 and X2, up to isomorphism, contradicting that C is indecomposable.
+□
+Definition 5.7. Let Q be any poset and let X be an object in Tame(Q, vectF). An exact sequence
+P := Pn−1 → · · · → P0 in Tame(Q, vectF), with Pi a free parametrized vector space for every
+0 ≤ i ≤ n − 1, is called an n-resolution of X if P → X → 0 is exact.
+An n-resolution P of X can also be seen as an object in Tame(Q, ch) together with a morphism
+P → X, where X is considered as a chain complex concentrated in degree 0.
+Definition 5.8. Let X be in Tame(Q, vectF). An n-resolution r: P → X is minimal if every
+morphism φ: P → P in Tame(Q, ch) such that r = r ◦ φ is an isomorphism.
+Remark 5.9. Every functor in Tame(R(Q), vectF) admits a 2-resolution [3, Proposition 10.3].
+Furthermore, if Q is finite and has dimension 1, then for minimal n-resolutions of functors in
+Tame(R(Q), vectF) we have n ≤ 2 [3, Theorem 10.19].
+The following statement is a standard observation in homological algebra.
+Remark 5.10. Let X be an object in Tame(R(Q), vectF). Then the minimal resolution of X and
+the minimal cover of X, thought as an object in Tame(Q, ch) concentrated in degree 0, coincide.
+Lemma 5.11. Let Q be a finite poset of dimension 1, X an object in Tame(R(Q), vectF), and
+P = P1 �→ P0 the minimal resolution of X. Then X is indecomposable in Tame(R(Q), vectF) if
+and only if P is indecomposable in Tame(R(Q), ch).
+Proof. Let us assume that P is indecomposable.
+By Remark 5.10, the minimal cover of X is
+indecomposable. Hence, by Lemma 5.6, X is indecomposable.
+Conversely, assume that P ∼= ˆP ⊕ P, with ˆP := ˆP1 �→ ˆP0 and P := P1 �→ P0. Thus, X ∼=
+ˆP0/ ˆP1 ⊕P0/P1. So, by the indecomposability of X, either ˆP0 ∼= ˆP1 or P0 ∼= P1. But this contradicts
+with minimality of P.
+□
+5.3. Characterization of cofibrant indecomposables. We can now prove the last main result
+of this work, which is a structure theorem for cofibrant indecomposable tame functors indexed by
+poset of dimension 1. The key steps are Lemmas 5.12 and 5.13. Together, they show that cofibrant
+indecomposables are nonzero in at most two consecutive degrees. Next, Theorem 5.16 classifies
+cofibrant indecomposables according to whether or not they are acyclic, and shows how to retrieve
+them from the indecomposables of Tame(R(Q), vectF).
+Lemma 5.12. Let Q be a poset of dimension 1, X an object in Tame(Q, ch) free in each degree,
+and HiX its i-th homology as object in Tame(Q, vectF). Le P = P1 �→ P0 be the minimal resolution
+of HiX. Then P is a direct summand of X.
+In the above statement, the hypothesis dim(Q) = 1 is necessary to ensure, by Remark 5.9, the
+existence of the minimal 2-resolution. Nevertheless, the lemma holds more in general, for any poset
+for which minimal 2-resolutions exist.
+Proof. We denote by P1
+d1
+�−−→ P0 → HiX the minimal free resolution of HiX, the i-th homology of
+X. Since Xi and P0 are both free and they map surjectively onto HiX, there exist lifts gi : P0 → Xi
+and hi : Xi → P0 fitting in the following commutative diagram:
+
+COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE
+13
+P0
+Xi
+P0
+HiX
+gi
+hi
+.
+The composition higi is an isomorphism because P0 → HiX is minimal.
+We next define the natural transformation hi+1 : Xi+1 → P1 pointwise. Here, the notation f x
+denotes the evaluation of f at x. For every x ∈ Q, we define hx
+i+1 : Xi+1(x) → P1(x) by setting, for
+every a ∈ Xi+1(x),
+hx
+i+1(a) :=
+�
+(dx
+1)−1(hx
+i ∂x
+i+1(a))
+if hx
+i ∂x
+i+1(a) ∈ im(dx
+1)
+0
+otherwise
+.
+This definition is well posed because d1 is a monomorphism. Observe that hi+1 is surjective be-
+cause every element in P1 is taken to 0 by the composition P1 �→ P0 ↠ HiX, i.e.
+im(d1) ⊆
+ker(X0 ↠ H0X) ∼= im(∂i+1). We define gi+1 : P1 → Xi+1 pointwise by setting b ∈ P1(x) �→ a ∈
+(∂x
+i+1)−1(hx
+i )−1dx
+1(b), where, if this preimage is not a singleton, we choose the unique element a such
+that hx
+i+1gx
+i+1(b) = (dx
+1)−1(hx
+i ∂x
+i+1(a)) = b. Again, gi+1 is well posed because d1 is a monomorphism.
+By construction, hi+1gi+1 is the identity. Thus, we have the following commutative diagram:
+P1
+Xi+1
+P1
+P0
+Xi
+P0
+HiX
+gi+1
+d1
+id
+hi+1
+d1
+gi
+id
+hi
+implying that X is isomorphic to the direct sum of X′ having trivial homology in degree i and
+P1 → P0.
+□
+In the above arguments, we repeatedly used the fact that the morphism P1 → P0 in the resolution
+is a monomorphism. Hence, this proof cannot be extended to longer resolutions. However, this is
+not a shortcoming of our arguments: as Remark 5.15 shows, Lemma 5.12 does not hold for longer
+resolutions. In plain words, if the dimension of the poset is greater than 1, then one can construct
+an indecomposable, free in each degree, nonzero in arbitrarily many degrees. Figure 3 shows one
+such object, nonzero in four degrees. Limiting the dimension to 1, avoids this behaviour.
+Lemma 5.13. Let Q be any poset. If X in Tame(Q, ch) is free in each degree and acyclic, then it
+is isomorphic to a finite direct sum of indecomposables, free in each degree, and nonzero in at most
+two consecutive degrees.
+Proof. Making the chain structure explicit, we write X as · · · X1
+∂1
+−→ X0 → 0. Since X is acyclic,
+∂1 is an epimorphism. Since X0 is free, X0
+id
+−→ X0 lifts to X0
+g−→ X1. We have X0
+g
+�−−→ X1
+∂1
+−−−↠ X0
+which means that X1 is isomorphic to X0 ⊕ X1, for some X1 ∈ Tame(Q, vectF).
+Thus, X is
+isomorphic to the direct sum of · · · → 0 → X0 → X0 and · · · → X2
+∂2
+−→ X1 → 0. By acyclicity, we
+
+14
+WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI
+can repeat the argument increasing the degree finitely many until the maximal nontrivial degree of
+X is reached.
+□
+Theorem 5.14. Let Q be a finite poset of dimension 1. If X in Tame(R(Q), ch) is cofibrant, then
+it is isomorphic to a direct sum of finitely many indecomposables that are cofibrant and nonzero in
+at most two consecutive degrees.
+Proof. The 0-th homology of X, H0X, is in Tame(R(Q), vectF). Thus it has a minimal free 2-
+resolution, P = P1 �→ P0 (see Remark 5.9). By Lemma 5.12, X is isomorphic to the direct sum of
+P and some X′. However, P is itself a direct sum of indecomposables that are degreewise free and
+nonzero in at most two consecutive degrees, whereas X′ is degreewise free and has trivial homology
+in degree 0.
+We can now repeat the argument finitely many times, increasing the homology degree until we
+reach the maximal nontrivial degree of X. What we obtain is a direct sum of indecomposables,
+degreewise free and nonzero in at most two consecutive degrees, together with an acyclic and
+degreewise free component. Thus, the claim follows by Lemma 5.13 and Lemma 5.2.
+□
+Remark 5.15. The poset Q depicted in Figure 4(c) is not of dimension 1. However, the object X
+described in Figure 3, indexed by Q, is indecomposable by Corollary 3.5. Moreover, a direct check
+shows that X is free in each degree. Therefore, Theorem 5.14 cannot be extended to posets of
+dimension greater than 1.
+Since, by the above result, all cofibrant indecomposables in Tame(Q, ch) are nonzero in at most
+two consecutive degrees, in what follows we can assume without loss of generality that they are
+nonzero in degrees 0 and 1.
+We are now ready to conclude with our structure theorem for cofibrant indecomposable objects
+in Tame(R(Q), ch).
+Theorem 5.16. Let Q be a finite poset of dimension 1 and X be an object in Tame(R(Q), ch). If
+X is cofibrant, then the following statements hold:
+(1) If X is indecomposable, then either H0X = 0 or H0X ̸= 0 and H0X is indecomposable;
+(2) If H0X ̸= 0 is indecomposable, then either X is indecomposable or X ∼= X′ ⊕ X′′ with
+X′, X′′ ̸= 0, H0X′ ̸= 0, and H0X′′ = 0;
+(3) If X is indecomposable and H0X = 0, then X is given by K[x, −)
+id
+−→ K[x, −) for some
+x ∈ Q.
+Proof. In order to prove (1) it is sufficient to show that if H0X ̸= 0 then H0X is indecomposable.
+Assume by contradiction that H0X is isomorphic to Z′ ⊕ Z′′, with Z′, Z′′ ̸= 0, in Tame(Q, vectF).
+Consider minimal 2-resolutions X′ → Z′ and X′′ → Z′′, so that X′ ⊕ X′′ → Z′ ⊕ Z′′ ∼= H0X is also
+a minimal 2-resolution. By Lemma 5.12, X′ ⊕ X′′, with X′, X′′ ̸= 0, is a summand of X, which
+contradicts the assumption of X indecomposable.
+To prove (2), it suffices to show that if X decomposes into X′ ⊕ X′′, with X′, X′′ ̸= 0 then
+H0X′ ̸= 0 and H0X′′ = 0.
+Assume this does not hold.
+Because H0X ∼= H0X′ ⊕ H0X′′, if
+H0X′ = H0X′′ = 0, then we contradict the assumption H0X ̸= 0; if H0X′, H0X′′ ̸= 0, then we
+contradict H0X being indecomposable. Hence, the claim.
+We now show (3). By Theorem 5.16, X is isomorphic to a direct sum of finitely many indecom-
+posables that are degreewise free and nonzero in at most two consecutive degrees. Since H0X = 0,
+these indecomposables are isomorphic to K[x, −)
+id
+−→ K[x, −), in degree 0 and 1. In addition, as X
+is assumed to be indecomposable, it is isomorphic to one of these summands.
+□
+
+REFERENCES
+15
+Acknowledgment. Wojciech Chach´olski and Francesca Tombari were partially supported by VR,
+the Wallenberg AI, Autonomous System and Software Program (WASP) funded by Knut and Alice
+Wallenberg Foundation, and MultipleMS funded by the European Union under the Horizon 2020
+program, grant agreement 733161, and dBRAIN collaborative project at digital futures at KTH.
+Barbara Giunti was supported by the Austrian Science Fund (FWF) P 33765-N. Claudia Landi
+carried out this work under the auspices of INdAM-GNSAGA and within the activities of ARCES
+(University of Bologna)
+References
+[1]
+Ibrahim Assem, Andrzej Skowronski, and Daniel Simson. Elements of the Representation The-
+ory of Associative Algebras: Techniques of Representation Theory. Vol. 1. London Mathematical
+Society Student Texts. Cambridge University Press, 2006. doi: 10.1017/CBO9780511614309.
+[2]
+Wojciech Chach´olski, Barbara Giunti, and Claudia Landi. “Invariants for tame parametrised
+chain complexes”. In: Homology, Homotopy, and Applications 23.2 (2021), pp. 183–213.
+[3]
+Wojciech Chach´olski, Alvin Jin, and Francesca Tombari. Realisations of posets and tameness.
+Preprint, available at arXiv:2112.12209. 2021.
+[4]
+William G. Dwyer and Jan Spali´nski. “Homotopy theories and model categories”. In: Handbook
+of Algebraic Topology (1995), pp. 73–126. doi: 10.1016/B978-044481779-2/50003-1.
+[5]
+Barbara Giunti. “Tame parametrised chain complexes”. PhD thesis. University of Pavia, 2019.
+[6]
+Michael Usher and Jun Zhang. “Persistent homology and Floer–Novikov theory”. In: Geometry
+and Topology 20 (2016), pp. 3333–3430.
+KTH Stockholm
+Email address: wojtek@kth.se
+Graz University of Technology
+Email address: bgiunti@tugraz.at
+University of Modena and Reggio Emilia
+Email address: clandi@unimore.it
+KTH Stockholm
+Email address: tombari@kth.se
+
diff --git a/WtE2T4oBgHgl3EQfuQi1/content/tmp_files/load_file.txt b/WtE2T4oBgHgl3EQfuQi1/content/tmp_files/load_file.txt
new file mode 100644
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+++ b/WtE2T4oBgHgl3EQfuQi1/content/tmp_files/load_file.txt
@@ -0,0 +1,602 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf,len=601
+page_content='COFIBRANT INDECOMPOSABLES IN CHAIN COMPLEX VALUED TAME  FUNCTORS INDEXED BY DIMENSION ONE POSETS  WOJCIECH CHACH´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In this work, we provide a model structure on full subcategories of tame objects in  functor categories indexed by continuous realizations of posets of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We also char-  acterize the indecomposable cofibrant objects when the landing category is the one of bounded  non-negative chain complexes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In addition, we present a general method to construct indecom-  posables in a functor category by a gluing technique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Introduction  In this article, we study the category of tame functors indexed by a poset Q and with values  in the category of bounded non-negative chain complexes of vector spaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We give conditions on  the poset Q under which this category has the projective model structure, and provide a structure  theorem for its cofibrant objects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The motivation comes from persistence theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Persistence theory is a discipline at the intersection of mathematics, computer science, and data  analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Its key feature is being able to avoid cherry-picking parameters in data analysis, studying  instead how the (topological) features evolve as the parameters change.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus objects arising in  persistence theory are indexed by a finite set of values, which however changes continuously from  one object to the other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Therefore, the natural language to treat them is the one of tame functor  categories, and the goal is to obtain computable invariants for these categories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In this work, we  focus on the theoretical backbone of persistence theory, in particular broadening the class of usable  indexing posets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We study functor categories whose indexing posets have dimension 1 (Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Intuitively,  this means that between any two comparable elements, there is only one monotone path.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This  ensures that there are well-behaved transformations from a finite poset to its continuous realization  and vice versa (Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This way, it is possible to define tame functor categories where, even  if the parameters are allowed to vary continuously, the information is always condensed in a finite  set of their values, providing a middle ground between generality and practicality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Indecomposables are a classical source for invariants, and thus understanding their behavior in  our categories of interest is essential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In Section 3, we present a method to construct indecom-  posables in any functor category landing in an abelian category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The idea is to “glue” together  objects with different indexing posets, such that one object is indecomposable and the other satisfies  certain conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus, one can start with a simple object, whose indecomposability is obvious,  and build more and more complex indecomposables by expanding the underlying poset using con-  ditions that are easier to verify than the indecomposability of the full object.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We will use this  technique to show that some of our following results about indecomposables intrinsically require  functors to be parametrized by posets of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Without this assumption, it is possible to  build indecomposables that are arbitrarily complicated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  1  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='04079v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='AT]  10 Jan 2023  2  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  The assumption that Q, if not finite, is the continuous realization [3] of a finite poset of dimension  1 also ensures the existence of the projective model structure on Tame(Q, M).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This is the full  subcategory of Fun(Q, M), where M is a model category, whose objects are functors which can  be expressed as the left Kan extensions along some finite subposet inclusion, D ⊂ Q (Section 4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  When the indexing poset is finite, the existence of such a model structure is a well-known fact [4],  but it is no longer guaranteed when the indexing poset is not finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We thus expand the class of  continuous posets for which Tame(Q, M) admits a model structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We are especially interested  in the case when M is ch, the category of bounded and non-negative chain complexes of vector  spaces, since parametrized chain complexes are part of the persistence pipeline (see also [6]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  In general, Tame(Q, ch) is of wild representation type, which means that finding a compact  description of the indecomposables is not feasible, so we cannot use them to define invariants  directly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' However, we can make use of the projective model structure: the latter provides a wealth  of ways to define invariants, for example via cofibrant approximations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Therefore, we concentrate  on cofibrant objects of Tame(Q, ch).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Cofibrant objects are characterized by being free degree-wise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We prove that, if the indexing poset has dimension 1, then the indecomposable cofibrant objects are  nonzero only in at most two consecutive degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This property allows us to prove one of our main  contribution: a structure theorem for cofibrant objects in Tame(Q, ch), when Q is the realization  of a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' More precisely, we show that all indecomposable cofibrant objects  in Tame(Q, ch) are suspensions of two types of indecomposables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' One type consists of the cones of  rank 1 free objects in Tame(Q, vectF), and the other consists of minimal covers of indecomposable  objects there.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Therefore, we can approximate any object in Tame(Q, ch) with an object that is no  more complicated to describe than an object in Tame(Q, vectF) but it carries more information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  In conclusion, we (1) prove the existence of the projective model structure on Tame(Q, M),  where M is a model category and Q is the continuous realization of a finite poset of dimension  1, (2) provide a technique to construct indecomposables in functor categories landing in abelian  categories, and (3) show a structure theorem for cofibrant objects in Tame(Q, ch), with Q as above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Preliminary results  The extraction of invariants from compact geometric objects, common in topological data anal-  ysis, gives rise to compact representations of posets in a certain category C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We call these represen-  tations of posets tame functors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' They are defined as left Kan extensions along poset functors from  a finite poset, which encode the relevant changes of the underlying geometric objects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset and C a category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A functor X : Q → C is called tame if there is  a functor α: D → Q from a finite poset D, and a functor Y : D → C such that X ∼= αKY , where αK  denotes the left Kan extension along α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The poset functor α: D → Q is called a discretization of  X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We denote by Tame (Q, C) the full subcategory given by all tame objects of Fun (Q, C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  If Q in the above definition is finite, then Tame(Q, C) and Fun(Q, C) coincide.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  If C is ch,  the category of bounded chain complexes over a field, we call X an object in Tame(Q, ch) a  (tame) parametrized chain complex, often omitting “tame” for simplicity, or a chain complex  indexed by Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  To the end of endowing the category of tame functors Tame(Q, M), where M is a model category  itself, with a model structure, which is the goal of Section 4, it is important that tame functors  admit all finite limits and colimits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' As for colimits, this is a consequence of left Kan extensions  being left adjoints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In order to guarantee that limits are also preserved when we take left Kan  extensions, we will consider transfers as a way to take a tame functor defined on an infinite poset  COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE  3  to a functor defined on a finite poset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The transfer construction requires additional assumptions  on posets: the existence of a transfer is ensured for posets obtained as realizations of posets of  dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Posets of dimension 1 and realizations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Given two elements p, x ∈ Q,  p is a parent of x if p < x and there exists no y ∈ Q such that p < y < x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The collection of parents  of x is denoted by P(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let S be a subposet of Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An element a ∈ Q is an ancestor of S if a ≤ x  for all x ∈ S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Note that if S = {x}, then P(x) is a subset of ancestors of x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If y ≤ x for every y  in S and there is no z in Q such that y ≤ z < x for every y in S, then x is a sup of S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If S has  a unique sup x, then this is called the coproduct (or join) of S, and it is denoted by � S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If I is  a poset and S is a set, the collection of functions f : S → I is denoted by IS and forms a poset:  f ≤ g in IS if and only if f(x) ≤ g(x), for every x in S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We use the symbol dom(f) to denote the  domain of f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Consider a subposet Q′ ⊆ Q and an element x in Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The subposet Q′ ≤ x (resp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Q′ < x) is defined as the intersection Q′ ∩ {y ∈ Q | y ≤ x} (resp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Q′ ∩ {y ∈ Q | y < x}).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset and x ∈ Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We say that x has dimension 1 in Q, denoted by  dimQ(x) = 1, if Q < x is not empty and x is not a sup of a 2-element subset of Q < x with an  ancestor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We say that x has dimension 0 if Q < x is empty.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A poset Q has dimension 1, denoted  by dim(Q) = 1, if dimQ(x) ≤ 1 for all x ∈ Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Examples of posets of dimension 1 include N and R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' R2 and the posets in Figure 4 are examples  of posets of dimension strictly greater than 1 (see [3, Paragraph 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1] for a definition of posets of  general dimension).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Its realization, denoted by R(Q), is the disjoint  union �  x∈Q  �  S⊆P(x)(−1, 0)S such that S is either empty or has cardinality 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  For each x ∈ Q, we identify the subset �  S⊆P(x),|S|=0(−1, 0)S = (−1, 0)∅ with (x, 0), and the  subset �  S⊆P(x),|S|=1(−1, 0)S = �  {p}⊆P(x)(−1, 0){p} with {(x, f) | and f : {p} → (−1, 0)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For  simplicity, we refer to an element of R(Q) as a pair (x, f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Intuitively, the realization of a poset of  dimension 1 is a continuous set, where the “gaps” between elements of the original poset are filled  by edges parametrized by (−1, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The realization of a poset is not just a set, but a poset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Given (x, f) and (y, g) in R(Q),  (y, g) ≤ (x, f) when one of the following conditions holds:  (x, f) = (x, 0) and y ≤ x,  y = x, dom(g) = dom(f) = p, and g(p) ≤ f(p),  y < x and y ≤ dom(f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We observe that Q can be identified with the subposet {(x, 0)}x∈Q of R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The realization of a poset of dimension 1 is a poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By a case analysis, one can show that the relation on R(Q) is reflexive, antisymmetric,  and transitive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' It remains to show that R(Q) has dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Fix x ∈ Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If dimQ(x) = 0,  then by construction also dimR(Q)(x, 0) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  If dimQ(x) = 1, then for every (x, f) in R(Q)  we have two cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  If dom(f) = ∅, then there exists y < x because dimQ(x) = 1, and hence  (y, 0) < (x, 0) = (x, f);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' if dom(f) ̸= ∅, then (y, 0) < (x, f), for y = dom(f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' From this we conclude  that R(Q) < (x, f) is not empty for every x such that dimQ(x) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Let us assume now by  contradiction that there is a (x, f) in R(Q) that is the sup of (y, g), (z, h) < (x, f) with a common  ancestor (a, l).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We observe that necessarily (x, f) = (x, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Assume that dom(g) and dom(h)  4  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  are non-empty.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then, since (x, f) is a sup of (y, g) and (z, h), and Q has dimension 1, dom(g)  and dom(h) are not comparable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This, together with the fact that (a, l) ≤ (y, g), (z, h), implies  that a < dom(g), dom(h) < x, which contradicts that Q has dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If (y, g) = (y, 0) and  dom(h) ̸= ∅, then a < y, dom(h) < x, which again contradicts Q being of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The cases  (z, h) = (z, 0) and dom(g) ̸= ∅, and (y, g) = (y, 0), (z, h) = (z, 0) are analogous.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Example 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Consider the poset N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then R(N) is isomorphic to the real interval [0, ∞).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Indeed,  the map R(N) → [0, ∞) that sends (x, 0) to x in N, and (x, f : {p} → (−1, 0)) to x + f(p), if x > 0,  is an isomorphism of posets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1 and R(Q) its realization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Consider a finite  subset V ⊂ (−1, 0) and define the subposet R(Q, V ) of R(Q) as R(Q, V ) := {(x, f) ∈ R(Q) |  f(dom(f)) ⊆ V or (x, f) = (x, 0)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We note that since Q is finite, R(Q, V ) is also finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An example is shown in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' i  i  i  i Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' From left to right: a poset Q of dimension 1, R(Q, V ) with V = { 1  4, 3  4},  and the realization R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In each poset, arrows point to greater elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Back and forth with transfer and left Kan extensions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We recall that a functor X : D →  C, where D is any poset and C is closed under finite colimits, can be extended as a left Kan extension  along an inclusion i: D ⊆ Q, so to obtain a new functor iKX : Q → C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The left Kan extension  is a functor iK : Fun(D, C) → Fun(Q, C) left adjoint to the pre-composition by i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  As such, it  commutes with colimits in Fun(Q, C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' However, it may fail to commute with limits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In order for  that commutativity to happen, we need additional hypotheses on the poset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In [3], the authors  showed that left Kan extensions preserve limits if the indexing poset is an upper semilattice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Our  first aim is to extend the class of posets for which this holds by proving an analogous result for  functors indexed by realizations of posets of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The idea for the proof is the following: first, we show that in the realization of a poset of  dimension 1 each downset, intersected with a certain subposet of the realization, admits a unique  sup, even if these posets are, in general, not upper semilattice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This is the key observation, as it  ensures that transfers are well defined (Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Using then the techniques of [3], we obtain  that the transfer is left adjoint to the inclusion of posets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Therefore, the precomposition with the  transfer is isomorphic to the left Kan extension, providing an explicit description of the latter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset of dimension 1 and V a finite subset of R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For every (x, f)  in R(Q), the coproduct �(R(Q, V ) ≤ (x, f)) exists in R(Q, V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Explicitly,  (1)  �  (R(Q, V ) ≤ (x, f)) =  �  (x, dom(f) �→ max Z(f))  if Z(f) ̸= ∅,  (p, 0)  if Z(f) = ∅.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  where Z(f) = {v ∈ V | f(dom(f)) ≥ v}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE  5  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Fix (x, f) ∈ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If (x, f) ∈ R(Q, V ), then �(R(Q, V ) ≤ (x, f)) = (x, f), and the claim is  true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' So, assume that (x, f) ̸∈ R(Q, V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since R(Q, V ) contains all elements of the form (x, 0), we  necessarily have that x is in Q and there exists a unique y = dom(f) in P(x) for which f(y) ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The subposet {(z, g) ∈ R(Q, V )) | (y, 0) ≤ (z, g) < (x, f)} is finite and totally ordered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus,  it admits a coproduct.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This coproduct is either (y, 0), if f(y) < min V , or (x, f ′), where f ′(y) =  max{v ∈ V | f(y) ≥ v}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' According to the partial order in R(Q), every element in R(Q, V ) ≤ (x, f)  is less than or equal to the coproduct of {(z, g) ∈ R(Q, V )) | (y, 0) ≤ (z, g) < (x, f)}, meaning that  the coproduct of the latter coincides with the coproduct of R(Q, V ) ≤ (x, f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='7 ensures that the following notion of transfer is well defined whenever Q is of  dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset of dimension 1 and consider the inclusion i: R(Q, V ) �→ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The function i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' : R(Q) → R(Q, V ) defined as i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (x, f) = �(R(Q, V ) ≤ (x, f)) is called the transfer  of i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The poset R(Q, V ) shown inside the poset R(Q), with R(Q, V ) and  R(Q) taken as in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The colored points (x, f) and (x, g) belong to R(Q),  and the corresponding arrows show the transfer applied to these points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  In plain words, pre-composition with the transfer allows for going from the continuous indexing  poset R(Q) back to a discretization R(Q, V ) of it using a finite subset V of (−1, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The following  remark makes this description, illustrated in Figure 2, rigorous.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For every (x, f) ∈ R(Q), we have the following (in)equalities:  (1) i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='i(x, f) = (x, f) ∈ R(Q, V ),  (2) ii!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (x, f) ≤ (x, f) ∈ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Following the tameness Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1, we consider tame functors parametrized by the continuous  poset R(Q), with Q a poset of dimension 1, as the left Kan extension of a finite discretization  R(Q, V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' As such, a tame functor indexed by the realization of a finite poset of dimension 1 is  constant between an element and its parent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' On the other hand, the transfer allows us to condense  the locally constant information encoded by tame functors into nodal points where the functor takes  different values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The functor (−)i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' : Fun(R(Q), C) → Fun(R(Q, V ), C) is left adjoint to the  functor (−)i : Fun(R(Q, V ), C) → Fun(R(Q), C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The proof follows by the same arguments of [3, Proposition 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4], which can be applied in our  setting by Definition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='8 and Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (1) and .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Since both (−)i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' and iK are left adjoint to (−)i, we obtain the following result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  i(α, 0) = (c, 0)  (c, f)  i(α,f)  (c, g)  i(c,g)6  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  Corollary 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset of dimension 1 and V a finite subset of (−1, 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For every  (x, f) ∈ R(Q, V ) and X ∈ Fun(R(Q, V ), C), iKX(x, f) ∼= Xi!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (x, f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  As above mentioned, the left Kan extension iK along the inclusion i: R(Q, V ) �→ R(Q) com-  mutes with colimits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We now prove that it also commutes with limits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For this to be true, it is  crucial that Q is a poset of dimension 1 because we use the transfer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let C be a category closed under finite (co)limits, Q a poset of dimension 1, V a  finite subposet of (−1, 0), and consider the inclusion i: R(Q, V ) �→ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The left Kan extension  iK : Fun (R(Q, V ), C) → Fun (R(Q), C) commutes with finite (co)limits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since left adjoints commute with colimits, we just need to show that iK commutes with  limits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Corollary 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='11 guarantees that, for X in Fun(R(Q, V ), C), iKX(x, f) is isomorphic to  Xi!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (x, f) = X (� (R(Q, V ) ≤ (x, f))).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let φ: D → Fun(R(Q, V ), C)) be a functor from a finite  category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The limit limD φ belongs to Fun(R(Q, V ), C) and, for every (x, f) ∈ R(Q), we have that  iK( limD φ)(x, f) ∼= ( limD φ)i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (x, f) = limD(φ(−)(i!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' (x, f))) ∼= limD(iKφ)(x, f)  where the first and last isomorphisms hold by Corollary 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  The last two results of this section allow us to restrict to the full subcategory of tame functors,  which is necessary to define a model structure (see Section 4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A functor X in Tame(R(Q), C) admits a dis-  cretization of the form i: R(Q, V ) �→ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since X is tame, there exist functors α: D → R(Q), with D a finite poset, and Y : D → C  such that X ∼= αKY .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Considering R(Q, V ), with V = {f(dom(f)) | (x, f) ∈ α(D)}, we have  α(D) ⊆ R(Q, V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since left Kan extensions commute with compositions, we have X ∼= αKY ∼=  (iα)KY = iK(αKY ), where i is the inclusion R(Q, V ) ⊂ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus, since R(Q, V ) is finite, X is  discretized by i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In addition to the assumptions in Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12, assume that Q is finite, and  let φ: D → Fun(R(Q), C) be a functor from a finite category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If φ(d) is tame for every object d in  D, then limD φ is also tame.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For every d in D, let id : R(Q, Vd) �→ R(Q), with Vd finite, be a discretising inclusion for  φ(d), which exists by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then i: R(Q, � Vd) �→ R(Q) discretises each φ(d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Moreover,  by Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9, the natural transformation φ(d) → iK(φ(d)i), adjoint to the identity φ(d)i → φ(d)i,  is an isomorphism, for every d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Consequently, limD φ is isomorphic to limD iK(φi), which is also  isomorphic to iK(limD φi), by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Hence, we have shown that limD φ is isomorphic to the  left Kan extension along i, implying that it is tame.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Generating indecomposables by gluing  In this section, we exhibit a general method to construct indecomposables in a functor category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  In particular, we give conditions under which it is possible to extend the indexing poset of an  indecomposable by gluing another object to it while preserving indecomposability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We first recall the following well-known result [1, Pag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 18]:  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' X : Q → C is indecomposable if and only if End(X) does not contain any non-trivial  idempotent elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE  7  Let now Q be any poset and X : Q → C be a functor with C an Abelian category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let A and B  be subposets of Q such that Q = A ∪ B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Denote by XA, XB and XA∩B the restrictions of X to  A, B and A ∩ B, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If XA is indecomposable and the morphism End(XB) → End(XA∩B), defined by the  restriction, is a monomorphism, then X is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1, we aim to show that End(X) contains only 0 and idX as idempotent elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Consider the maps End(XA) → End(XA∩B) ←� End(XB) induced by the restrictions, the right one  being a monomorphism by hypothesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' They fit into the following diagram where P is their pullback:  End(X)  P  End(XB)  End(XA)  End(XA∩B)  β  γ  α  By a property of pullbacks, P → End(XA) is also a monomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since P is isomorphic to  {(ϕ, ψ) ∈ End(XA) ⊕ End(XB) | ϕ|A∩B = ψ|A∩B} and α and β are induced by the restrictions  of X to A and B, respectively, the morphism γ is a monomorphism, which implies that α is also  a monomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since α is induced by the restriction of X to A, it sends idempotent elements  of End(X) to idempotent elements of End(XA).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In particular, if ϕ is an idempotent element of  End(X), then γϕ = ϕ|A is also idempotent in End(XA).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By indecomposability of XA, ϕ|A can  either be 0 or idX|A, and then, since γ is a monomorphism, ϕ must be either 0 or idX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Our goal is now to determine under which circumstances End(XB) includes into End(XA∩B).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Given the diagram  (2)  Y  X  Y  X  β  η  ν  β  ,  there exists at most one ν making the diagram commute if, and only if, hom (coker β, X) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Consider the following right exact sequence: Y  β−→ X ↠ coker β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By applying hom(−, X)  and hom(−, Y ) to it, we obtain the following commutative diagram:  hom(Y, X)  hom(X, X)  hom(coker β, X)  0  hom(Y, Y )  hom(X, Y )  hom(coker β, Y )  0  β∗  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The condition hom(coker β, X) = 0 is equivalent to β∗ being a monomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let us take ξ ∈  hom(Y, X) to be the image of η ∈ hom(Y, Y ) along the leftmost vertical map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The preimage of ξ  under β∗ is either empty or exactly one morphism ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let A and B be subposets of Q such that Q = A∪B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let X : Q → C be a functor and  let β : iKXA∩B → XB be the unique morphism given by the universality of the left Kan extension  8  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  along the inclusion i: A ∩ B → B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If hom(coker β, XB) = 0 and XA is indecomposable, then X is  indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We need to show that the morphism End(XB) �→ End(XA∩B).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2, this, together  with the assumption that XA is indecomposable, implies that X is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Assume that  there are two endomorphisms of XB, ν and ν′, such that their restrictions to A ∩ B coincide.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The  endomorphism η induced by their left Kan extension along the inclusion of A ∩ B into B fits into  the following diagram:  (3)  iKXA∩B  XB  iKXA∩B  XB  β  η  ν  ν′  β  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Thus, by Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3, ν = ν′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Next, we exemplify how to construct complex indecomposables using this technique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This ex-  ample also shows that Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='14 does not hold if the dimension of the indexing poset is not 1  (see Section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  F  F2  F  F  F  F  F  F  F3  F  F  F3  F  F  F  F  F  F  F  F  F  F  F  �  0  1  �  �  1  0  �  �  �  0  1  0  �  �  �  1  0  �  �  1  1  �  �  �  0  1  0  �  �  �  �  1  0  0  �  �  �  1  0  0�  �  1  0  0�  �  �  0  0  1  �  �  �  �  1  1  1  �  �  �  �  0  0  1  �  �  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A parametrized chain complex X (for its indexing poset see Figure 4c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Only its non-trivial maps are displayed and they are given by the identity if not  otherwise specified.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Vertical maps are all chain maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Corollary 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The object X in Fun(Q, ch) defined as shown in Figure 3 is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The proof follows by repeatedly applying Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4 to the restrictions of X to the series  of posets depicted in Figure 4, since XA is step (A) is clearly indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Indeed, in all three  steps, iKXA∩B is nonzero in fewer degrees than XB (precisely, nonzero only in degree 0 in step  COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE  9  (A), 0 and 1 in step (B), and 1 in step (C)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Therefore, coker β is zero in the same degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' So, by  commutativity, the only possible morphism between coker β and XB is the zero morphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  A  B  (a)  A  B  (b)  A  B  (c)  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Posets used to construct the indecomposable object shown in Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Model categories indexed by posets  In this section we show that it is possible to endow the category Tame(R(Q), M) with a model  structure whenever M is a model category itself and Q is a poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Because R(Q)  is not a finite poset, this is an advancement with respect to the known result for finite posets [4],  which we will briefly recall for the reader’s convenience.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' It is also a new result with respect to [2]  and [3], where the indexing poset is required to be [0, ∞) and an upper semilattice, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1 ([4]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset and M a model category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  In Tame (Q, M) we  define weak equivalences and fibrations pointwisely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Moreover, a morphism ϕ: X → Y in  Tame (Q, M) is said to be a cofibration if, for every x ∈ Q, the mediating morphism  ˆϕx : colim (colimQ<x Y ← colimQ<x X → X(x)) → Y (x)  in the pushout diagram  (4)  colimQ<x X  X(x)  colimQ<x Y  P  Y (x)  colimQ<x ϕ  ˆϕx  is a cofibration in M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  As weak equivalences and fibrations are defined pointwisely, the above-defined structure is usu-  ally referred to as a projective model structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We now extend this model structure to the  continuous case given by tame functors indexed by realizations of finite posets of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Given a model category M and a finite poset Q of dimension 1, a morphism  ϕ: X → Y in Tame (R(Q), M) is said to be a  weak equivalence if ϕ(x, f) is a weak equivalence in M for all (x, f) ∈ R(Q);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  fibration if ϕ(x, f) is a fibration in M for all (x, f) ∈ R(Q);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  10  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  cofibration if there is a finite set V ⊆ (−1, 0] with an inclusion i: R(Q, V ) �→ R(Q) dis-  cretising both X and Y , such that iKϕ: iKX → iKY is a cofibration in Tame (R(Q, V ), M).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Note that, in the definition of a cofibration, the existence of a common discretisation is guaranteed  by [3, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let M be a model category, Q a finite poset of dimension 1, and i: R(Q, V ) �→  R(Q) a poset inclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If a morphism ϕ: F → G in Fun(R(Q, V ), M) is a weak equivalence (resp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  a fibration), then so is its left Kan extension iKϕ: iKF → iKG in Fun(R(Q), M).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thanks to Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='7, we can apply the same arguments of [3, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Assume that Q is a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' With the choices of fibrations,  cofibrations, and weak equivalences as in Definition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2, Tame (R(Q), M) is a model category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The first axiom of a model category is satisfied by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The rest of the proof follows  from the same arguments of [3, Th.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3], using Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9, Corollary 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='11 and Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3 to  obtain the same guarantees given by upper semilattices in [3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  In what follows, we overload the symbol Tame(R(Q), ch) to denote the model category given by  Definition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A model structure allows for the following notion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An object X in a model category is cofibrant if the unique morphism from the  initial object of the category to X is a cofibration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Cofibrant objects are interesting at a theoretical level since, by the factorization axiom, any  object X in a model category can be “approximated” by its cofibrant replacement, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  a  cofibrant object that maps to X as a fibration and a weak equivalence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Usually cofibrant objects  have more properties than general objects and thus are easier to handle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In computation, they  provide a wealth of invariants (see [2]) such as the minimal cover (discussed in Section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Chain complexes parametrized by posets of dim 1  In this section we particularize the model structure introduced in Section 4 by taking M to be the  category of bounded chain complexes, ch, with its standard model structure [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We provide insight  into the structure of cofibrant objects and, particularly, into cofibrant indecomposables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' While some  results in Sections 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1 and 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2 can be generalized to other settings in which Tame(Q, ch) admits a  projective model structure without Q being of dimension 1, the results presented in Section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3 are  strongly dependent on the fact that the indexing poset is of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The restriction of an object X in Tame (Q, ch) to a fixed degree n ∈ N is denoted by Xn, and  it can be seen as an object in Tame (Q, vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We denote the parametrized chain maps of X by  ∂n : Xn → Xn−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An object X in Tame(Q, ch) is said to be nonzero in (at most) two consec-  utive degrees if there exists i ∈ N such that Xj = 0 if j ̸= i, i + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' It is said to be acyclic if  HnX ∼= 0 for every n ∈ N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  For example, X = 0 is nonzero in two consecutive degrees (for any choice of i ∈ N) and acyclic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE  11  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Cofibrancy and freeness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We show that the notion of cofibrancy in Tame (R(Q), ch) is  strongly related to that of freeness in the category Tame (R(Q), vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' This result is fundamental  in view of Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='14 to characterize cofibrant indecomposables in the category Tame(R(Q), ch).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  For any poset Q, we say a functor in Tame (Q, vectF) to be a parametrized vector space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Such an object is free if it is isomorphic to ⊕x∈SF[x, −) for some finite S ⊆ Q, where, for every  y ≤ y′,  F[x, y) =  �  F  if x ≤ y  0  otherwise  ,  F[x, y) → F[x, y′) =  �  idF  if x ≤ y ≤ y′  0  otherwise  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An object X in Tame (R(Q), ch) is cofibrant  if and only if, for all n ∈ N, Xn is free in Tame (R(Q), vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For (x, f) ∈ R(Q), let us consider the mediating morphism ˆϕ(x,f) : P → X(x, f) whose  domain is the pushout P := colim  �  colimR(Q)<(x,f) ← 0 → 0  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By Definitions 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2 and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='5, X is  cofibrant if and only if ˆϕ(x,f) is a monomorphism for every (x, f) ∈ R(Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A direct computation  shows that ˆϕ(x,f) is a monomorphism if and only if X is free in each degree, giving the claim.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Minimality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We decline the concept of minimality in the model category Tame(R(Q), ch)  and in Tame(R(Q), vectF), with the goal of defining invariants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We first prove the existence of  minimal covers in Tame(R(Q), ch).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then we show some of their properties and those of minimal  resolutions in Tame(R(Q), vectF), in particular with regard to indecomposable objects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' To ensure  that Tame(R(Q), ch) is a model category, we assume Q to be a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The minimal cover of an object X  in Tame(R(Q), ch) is a morphism π: C → X that is a weak equivalence and a fibration, with C  cofibrant, and such that any endomorphism φ: C → C that satisfies π = π ◦ φ is an isomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The minimal cover is a particular cofibrant approximation that needs not exist in any model  category but it is unique if it does, thus providing an invariant (see [2] for a general description).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' A morphism π: C → X in Tame(R(Q), ch)  is a minimal cover if and only C is cofibrant, π is a fibration and a weak equivalence, and no acyclic  direct summand of C is in the kernel of π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Follows by arguments analogous to those of [2, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1], since Tame(R(Q), ch) is a Krull-  Schmidt category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Every object X in Tame(R(Q), ch) admits  a minimal cover.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For every object X in Tame(R(Q), ch), let us consider its cofibrant replacement p: C′ → X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Since Tame(R(Q), ch) is a Krull-Schmidt category, we can decompose C′ into indecomposables and  remove all the acyclic indecomposable summands that are sent to zero via p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The resulting map is  a minimal cover by Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1, X an object in Tame(R(Q), ch) and C  π  −−−↠ X  its minimal cover.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If C is indecomposable, then X is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  12  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By arguing as in [5, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='21], we see that the minimal cover preserves direct sums.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus,  if X ∼= X1 ⊕ X2, then the minimal cover C of X decomposes into the sum of the minimal covers of  X1 and X2, up to isomorphism, contradicting that C is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Definition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be any poset and let X be an object in Tame(Q, vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An exact sequence  P := Pn−1 → · · · → P0 in Tame(Q, vectF), with Pi a free parametrized vector space for every  0 ≤ i ≤ n − 1, is called an n-resolution of X if P → X → 0 is exact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  An n-resolution P of X can also be seen as an object in Tame(Q, ch) together with a morphism  P → X, where X is considered as a chain complex concentrated in degree 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Definition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let X be in Tame(Q, vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' An n-resolution r: P → X is minimal if every  morphism φ: P → P in Tame(Q, ch) such that r = r ◦ φ is an isomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Every functor in Tame(R(Q), vectF) admits a 2-resolution [3, Proposition 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Furthermore, if Q is finite and has dimension 1, then for minimal n-resolutions of functors in  Tame(R(Q), vectF) we have n ≤ 2 [3, Theorem 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The following statement is a standard observation in homological algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let X be an object in Tame(R(Q), vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then the minimal resolution of X and  the minimal cover of X, thought as an object in Tame(Q, ch) concentrated in degree 0, coincide.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1, X an object in Tame(R(Q), vectF), and  P = P1 �→ P0 the minimal resolution of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then X is indecomposable in Tame(R(Q), vectF) if  and only if P is indecomposable in Tame(R(Q), ch).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let us assume that P is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  By Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='10, the minimal cover of X is  indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Hence, by Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='6, X is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Conversely, assume that P ∼= ˆP ⊕ P, with ˆP := ˆP1 �→ ˆP0 and P := P1 �→ P0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus, X ∼=  ˆP0/ ˆP1 ⊕P0/P1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' So, by the indecomposability of X, either ˆP0 ∼= ˆP1 or P0 ∼= P1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' But this contradicts  with minimality of P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Characterization of cofibrant indecomposables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We can now prove the last main result  of this work, which is a structure theorem for cofibrant indecomposable tame functors indexed by  poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The key steps are Lemmas 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12 and 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Together, they show that cofibrant  indecomposables are nonzero in at most two consecutive degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Next, Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='16 classifies  cofibrant indecomposables according to whether or not they are acyclic, and shows how to retrieve  them from the indecomposables of Tame(R(Q), vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a poset of dimension 1, X an object in Tame(Q, ch) free in each degree,  and HiX its i-th homology as object in Tame(Q, vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Le P = P1 �→ P0 be the minimal resolution  of HiX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Then P is a direct summand of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  In the above statement, the hypothesis dim(Q) = 1 is necessary to ensure, by Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9, the  existence of the minimal 2-resolution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Nevertheless, the lemma holds more in general, for any poset  for which minimal 2-resolutions exist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We denote by P1  d1  �−−→ P0 → HiX the minimal free resolution of HiX, the i-th homology of  X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since Xi and P0 are both free and they map surjectively onto HiX, there exist lifts gi : P0 → Xi  and hi : Xi → P0 fitting in the following commutative diagram:  COFIBRANT INDECOMPOSABLES AND POSETS OF DIMENSION ONE  13  P0  Xi  P0  HiX  gi  hi  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  The composition higi is an isomorphism because P0 → HiX is minimal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We next define the natural transformation hi+1 : Xi+1 → P1 pointwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Here, the notation f x  denotes the evaluation of f at x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' For every x ∈ Q, we define hx  i+1 : Xi+1(x) → P1(x) by setting, for  every a ∈ Xi+1(x),  hx  i+1(a) :=  �  (dx  1)−1(hx  i ∂x  i+1(a))  if hx  i ∂x  i+1(a) ∈ im(dx  1)  0  otherwise  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  This definition is well posed because d1 is a monomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Observe that hi+1 is surjective be-  cause every element in P1 is taken to 0 by the composition P1 �→ P0 ↠ HiX, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  im(d1) ⊆  ker(X0 ↠ H0X) ∼= im(∂i+1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We define gi+1 : P1 → Xi+1 pointwise by setting b ∈ P1(x) �→ a ∈  (∂x  i+1)−1(hx  i )−1dx  1(b), where, if this preimage is not a singleton, we choose the unique element a such  that hx  i+1gx  i+1(b) = (dx  1)−1(hx  i ∂x  i+1(a)) = b.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Again, gi+1 is well posed because d1 is a monomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  By construction, hi+1gi+1 is the identity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus, we have the following commutative diagram:  P1  Xi+1  P1  P0  Xi  P0  HiX  gi+1  d1  id  hi+1  d1  gi  id  hi  implying that X is isomorphic to the direct sum of X′ having trivial homology in degree i and  P1 → P0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  In the above arguments, we repeatedly used the fact that the morphism P1 → P0 in the resolution  is a monomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Hence, this proof cannot be extended to longer resolutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' However, this is  not a shortcoming of our arguments: as Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='15 shows, Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12 does not hold for longer  resolutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In plain words, if the dimension of the poset is greater than 1, then one can construct  an indecomposable, free in each degree, nonzero in arbitrarily many degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Figure 3 shows one  such object, nonzero in four degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Limiting the dimension to 1, avoids this behaviour.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be any poset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If X in Tame(Q, ch) is free in each degree and acyclic, then it  is isomorphic to a finite direct sum of indecomposables, free in each degree, and nonzero in at most  two consecutive degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Making the chain structure explicit, we write X as · · · X1  ∂1  −→ X0 → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since X is acyclic,  ∂1 is an epimorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since X0 is free, X0  id  −→ X0 lifts to X0  g−→ X1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' We have X0  g  �−−→ X1  ∂1  −−−↠ X0  which means that X1 is isomorphic to X0 ⊕ X1, for some X1 ∈ Tame(Q, vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Thus, X is  isomorphic to the direct sum of · · · → 0 → X0 → X0 and · · · → X2  ∂2  −→ X1 → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By acyclicity, we  14  WOJCIECH CHACH ´OLSKI, BARBARA GIUNTI, CLAUDIA LANDI, AND FRANCESCA TOMBARI  can repeat the argument increasing the degree finitely many until the maximal nontrivial degree of  X is reached.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If X in Tame(R(Q), ch) is cofibrant, then  it is isomorphic to a direct sum of finitely many indecomposables that are cofibrant and nonzero in  at most two consecutive degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The 0-th homology of X, H0X, is in Tame(R(Q), vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus it has a minimal free 2-  resolution, P = P1 �→ P0 (see Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12, X is isomorphic to the direct sum of  P and some X′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' However, P is itself a direct sum of indecomposables that are degreewise free and  nonzero in at most two consecutive degrees, whereas X′ is degreewise free and has trivial homology  in degree 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We can now repeat the argument finitely many times, increasing the homology degree until we  reach the maximal nontrivial degree of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' What we obtain is a direct sum of indecomposables,  degreewise free and nonzero in at most two consecutive degrees, together with an acyclic and  degreewise free component.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Thus, the claim follows by Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='13 and Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  Remark 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='15.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' The poset Q depicted in Figure 4(c) is not of dimension 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' However, the object X  described in Figure 3, indexed by Q, is indecomposable by Corollary 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Moreover, a direct check  shows that X is free in each degree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Therefore, Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='14 cannot be extended to posets of  dimension greater than 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Since, by the above result, all cofibrant indecomposables in Tame(Q, ch) are nonzero in at most  two consecutive degrees, in what follows we can assume without loss of generality that they are  nonzero in degrees 0 and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We are now ready to conclude with our structure theorem for cofibrant indecomposable objects  in Tame(R(Q), ch).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Let Q be a finite poset of dimension 1 and X be an object in Tame(R(Q), ch).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' If  X is cofibrant, then the following statements hold:  (1) If X is indecomposable, then either H0X = 0 or H0X ̸= 0 and H0X is indecomposable;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  (2) If H0X ̸= 0 is indecomposable, then either X is indecomposable or X ∼= X′ ⊕ X′′ with  X′, X′′ ̸= 0, H0X′ ̸= 0, and H0X′′ = 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  (3) If X is indecomposable and H0X = 0, then X is given by K[x, −)  id  −→ K[x, −) for some  x ∈ Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In order to prove (1) it is sufficient to show that if H0X ̸= 0 then H0X is indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Assume by contradiction that H0X is isomorphic to Z′ ⊕ Z′′, with Z′, Z′′ ̸= 0, in Tame(Q, vectF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Consider minimal 2-resolutions X′ → Z′ and X′′ → Z′′, so that X′ ⊕ X′′ → Z′ ⊕ Z′′ ∼= H0X is also  a minimal 2-resolution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12, X′ ⊕ X′′, with X′, X′′ ̸= 0, is a summand of X, which  contradicts the assumption of X indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  To prove (2), it suffices to show that if X decomposes into X′ ⊕ X′′, with X′, X′′ ̸= 0 then  H0X′ ̸= 0 and H0X′′ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Assume this does not hold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Because H0X ∼= H0X′ ⊕ H0X′′, if  H0X′ = H0X′′ = 0, then we contradict the assumption H0X ̸= 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' if H0X′, H0X′′ ̸= 0, then we  contradict H0X being indecomposable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Hence, the claim.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  We now show (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' By Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='16, X is isomorphic to a direct sum of finitely many indecom-  posables that are degreewise free and nonzero in at most two consecutive degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Since H0X = 0,  these indecomposables are isomorphic to K[x, −)  id  −→ K[x, −), in degree 0 and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In addition, as X  is assumed to be indecomposable, it is isomorphic to one of these summands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  □  REFERENCES  15  Acknowledgment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Wojciech Chach´olski and Francesca Tombari were partially supported by VR,  the Wallenberg AI, Autonomous System and Software Program (WASP) funded by Knut and Alice  Wallenberg Foundation, and MultipleMS funded by the European Union under the Horizon 2020  program, grant agreement 733161, and dBRAIN collaborative project at digital futures at KTH.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Barbara Giunti was supported by the Austrian Science Fund (FWF) P 33765-N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Claudia Landi  carried out this work under the auspices of INdAM-GNSAGA and within the activities of ARCES  (University of Bologna)  References  [1]  Ibrahim Assem, Andrzej Skowronski, and Daniel Simson.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Elements of the Representation The-  ory of Associative Algebras: Techniques of Representation Theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Vol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' London Mathematical  Society Student Texts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Cambridge University Press, 2006.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1017/CBO9780511614309.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  [2]  Wojciech Chach´olski, Barbara Giunti, and Claudia Landi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' “Invariants for tame parametrised  chain complexes”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In: Homology, Homotopy, and Applications 23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='2 (2021), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 183–213.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  [3]  Wojciech Chach´olski, Alvin Jin, and Francesca Tombari.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Realisations of posets and tameness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  Preprint, available at arXiv:2112.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='12209.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  [4]  William G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' Dwyer and Jan Spali´nski.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' “Homotopy theories and model categories”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In: Handbook  of Algebraic Topology (1995), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 73–126.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='1016/B978-044481779-2/50003-1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  [5]  Barbara Giunti.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' “Tame parametrised chain complexes”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' PhD thesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' University of Pavia, 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  [6]  Michael Usher and Jun Zhang.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' “Persistent homology and Floer–Novikov theory”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' In: Geometry  and Topology 20 (2016), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content=' 3333–3430.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='  KTH Stockholm  Email address: wojtek@kth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='se  Graz University of Technology  Email address: bgiunti@tugraz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='at  University of Modena and Reggio Emilia  Email address: clandi@unimore.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='it  KTH Stockholm  Email address: tombari@kth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
+page_content='se' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/WtE2T4oBgHgl3EQfuQi1/content/2301.04079v1.pdf'}
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+1
+Computer Vision and Image Understanding
+journal homepage: www.elsevier.com
+Simplifying Open-Set Video Domain Adaptation with Contrastive Learning
+Giacomo Zaraa, Victor Guilherme Turrisi da Costaa, Subhankar Royb, Paolo Rotaa, Elisa Riccia,b
+aUniversity of Trento, Via Sommarive 9, Trento, Italy
+bFondazione Bruno Kessler, Via Sommarive 18, Trento, Italy
+ABSTRACT
+In an effort to reduce annotation costs in action recognition, unsupervised video domain adaptation
+methods have been proposed that aim to adapt a predictive model from a labelled dataset (i.e., source
+domain) to an unlabelled dataset (i.e., target domain). In this work we address a more realistic scenario,
+called open-set video domain adaptation (OUVDA), where the target dataset contains “unknown”
+semantic categories that are not shared with the source. The challenge lies in aligning the shared
+classes of the two domains while separating the shared classes from the unknown ones. In this work we
+propose to address OUVDA with an unified contrastive learning framework that learns discriminative
+and well-clustered features. We also propose a video-oriented temporal contrastive loss that enables
+our method to better cluster the feature space by exploiting the freely available temporal information
+in video data. We show that discriminative feature space facilitates better separation of the unknown
+classes, and thereby allows us to use a simple similarity based score to identify them. We conduct
+thorough experimental evaluation on multiple OUVDA benchmarks and show the effectiveness of our
+proposed method against the prior art.
+© 2023 Elsevier Ltd. All rights reserved.
+1. Introduction
+Action recognition is an important problem in the field of
+computer vision where the task consists in recognizing the ac-
+tion being performed in a video sequence. Supervised action
+recognition (Tran et al., 2015; Feichtenhofer et al., 2016; Car-
+reira and Zisserman, 2017; Zhou et al., 2018) is widely stud-
+ied because of the growing need for automatically categorizing
+video content that are being generated everyday. However, it is
+nearly impossible for human annotators to keep pace with the
+enormous volumes of online videos, and thus supervised train-
+ing becomes infeasible. A cheaper way of leveraging the mas-
+sive pool of unlabelled data is by exploiting an already trained
+model to infer the labels on such data and then re-using them
+to build an improved model. Such an approach is also prone
+to failure because the unlabelled data may belong to a data dis-
+tribution that is different from the annotated one, which is of-
+ten referred to as the domain-shift problem (Torralba and Efros,
+2011).
+To address the domain-shift problem, Unsupervised Video
+Domain Adaptation (UVDA) methods (Chen et al., 2019; Choi
+et al., 2020; Pan et al., 2020) have been proposed that aim
+to learn a model for the domain of interest by jointly lever-
+aging the annotated source data and the unannotated target
+data.
+However, these methods make a strong and unrealis-
+tic assumption that the source and target domains share the
+same label space, which is also known as the closed-set sce-
+nario. The closed-set assumption is rarely the case in the real
+world as the target domain can contain video sequences from
+action categories that are not present in the source dataset. Such
+non-overlapping categories are known as the out-of-distribution
+(OOD) classes (Vaze et al., 2022). A naive application of the
+existing UVDA techniques will cause the model to incorrectly
+classify the OOD classes as one of the shared ones, which is
+undesirable.
+Due to the limited applicability of the closed-set UVDA set-
+ting, the focus has been shifting towards the more challeng-
+ing open-set scenario where the target dataset contains samples
+associated with categories that are not present in the source do-
+main. In the context of action recognition, this task is referred to
+as the Open-Set Unsupervised Video Domain Adaptation (OU-
+VDA) (Chen et al., 2021). The main goal in OUVDA consists in
+adapting a model to the target domain that can align the classes
+that are shared between the two domains while excluding the
+OOD (also known as target-private or unknown) classes from
+the alignment process. Although open-set unsupervised domain
+arXiv:2301.03322v1  [cs.CV]  9 Jan 2023
+
+ELSEVLER2
+adaptation has received significant attention for the image clas-
+sification task (Saito et al., 2018b, 2020; Bucci et al., 2020;
+Saito and Saenko, 2021; Bucci et al., 2021), it is rather under-
+studied in the field of action recognition (Chen et al., 2021).
+The recently proposed OUVDA method, CEVT (Chen et al.,
+2021), uses a weighted adversarial learning strategy, with the
+weights derived from class-conditional extreme value theory,
+in order to recognize the target-private classes. However, ad-
+versarial learning-based alignment can be unstable in practice,
+especially in the open-set scenarios. In this work, we argue that
+OUVDA can be greatly simplified if we can learn discrimina-
+tive features on both the source and target data for the following
+two reasons: (i) it can implicitly align the shared classes be-
+tween the source and target domains by learning semantically
+distinct clusters (Wang and Isola, 2020); and (ii) it results in
+the target-private classes being well separated from the shared
+ones (see Fig. 1). Based on this intuition, we propose to lever-
+age contrastive learning (Gutmann and Hyv¨arinen, 2010; Chen
+et al., 2020; He et al., 2020) to obtain discriminative represen-
+tations to tackle OUVDA.
+In details, we realize the above goals by proposing to use
+different instantiations of the contrastive loss that mainly dif-
+fer in how the positives and negatives are mined. To recap, the
+contrastive loss (Chen et al., 2020) relies on positives and neg-
+atives which are then contrasted to learn feature representation.
+In our proposed method we use four such instantiations of con-
+trastive loss: (i) a label-based supervised contrastive loss for
+the source; (ii) an augmentation-based contrastive loss for the
+target; (iii) a cross-domain contrastive loss between the source
+and the pseudo-labelled target; and (iv) a temporal contrastive
+loss to learn the temporal dynamics present in video data. One
+important advantage with such a proposal is that we can lever-
+age an unique contrastive formulation to unify several losses,
+which cater to different learning aspects of the task at hand. It
+also ensures compatible gradients and dispose of the need of
+tuning several hyperparameters. To this end, we call our pro-
+posed method COLOSEO (COntrastive Learning for Open-
+SEt VideO Domain Adaptation).
+Owing to the well-clustered feature space we observe that it
+becomes fairly straightforward to separate the target-private in-
+stances from the shared ones. In this work we use the nearest
+class prototypes (Mensink et al., 2013) with a simple cosine-
+similarity metric to exclude the target-private instances from
+the alignment process that lie far from all the source classes
+prototypes. We extensively validate our proposed method on
+multiple benchmarks: (i) HMDB↔UCF and UCF↔Olympic
+that contains actions from third-person view; and (ii) the chal-
+lenging first-person (egocentric) Epic-Kitchens.
+Contributions. To summarize, our main contributions are:
+(i) the COLOSEO framework, which uses an unified con-
+trastive learning formulation to address the task of OUVDA.
+We demonstrate that learning compact and discriminative fea-
+ture representations can greatly simplify the OUVDA task;
+(ii) a novel video-oriented temporal contrastive loss that im-
+proves the OOD robustness, thereby facilitating the task at
+hand; (iii) we advance the state-of-the-art on three standard OU-
+VDA benchmarks by non-trivial margins.
+PUSH
+PUSH
+PULL
+"horse riding"
+"horse riding"
+"shooting bow"
+"shooting bow"
+source class 1
+source class 1
+target class 1
+target class 2
+target private
+class prototype
+"climb" (unknown)
+Fig. 1: An illustration of a feature space learned with contrastive learning in
+order to obtain discriminative video features. A well-clustered feature space
+simplifies the separation of the shared classes from the out-of-distribution (or
+target-private) ones.
+2. Related Works
+Open-set Unsupervised Domain Adaptation. There exists
+a large body of the open-set unsupervised domain adaptation
+(OUDA) literature but applied specifically to the image classi-
+fication task. OUDA was first introduced by Panareda Busto
+and Gall (2017) and later then addressed in several subsequent
+works, which mostly rely either on adversarial learning or clus-
+tering approaches.
+Most of the initial works (Saito et al., 2018b; Shermin et al.,
+2021) exploited adversarial learning to detect target-private
+samples while aligning features of different domains for the
+known categories. Fu et al. (2019) improved the adversarial ob-
+jective of Saito et al. (2018b) by replacing the binary cross en-
+tropy loss with a symmetrical Kullback-Leibler distance-based
+loss. Liu et al. (2019) addressed OUDA by training a multi-
+binary classifier with source data, alongside domain discrim-
+inator, to progressively separate the samples of unknown and
+known classes. A graph neural network based approach was
+proposed by Luo et al. (2020) that integrates episodic pseudo-
+labelling with adversarial learning to tackle the OUDA task.
+Recently, the adversarial approaches have been replaced by
+clustering-based methods (Wang, 2021) that ensure well clus-
+tered target space. For instance, Bucci et al. (2021) proposed
+HyMOS that uses contrastive learning to enforce invariance to
+the augmentations obtained via style transfer. However, Hy-
+MOS is tailored for the multi-source OUDA setting. Ma et al.
+(2021) introduced a method for active OUDA that combines
+adversarial learning with the clustering non-transferable gra-
+dient embedding approach. Recently, Saito et al. (2020) pro-
+posed DANCE that uses self-supervision to cluster the target
+
+3
+data, followed by detecting the target-private instances based
+on the entropy computed by the classifier. Different to all other
+approaches, OVANet (Saito and Saenko, 2021) trains one-vs-all
+binary open set classifiers on the source data to detect and re-
+ject the unknown samples. A common theme in all these above
+methods is that they are have been proposed for images and do
+not exploit the temporal information which video data has to
+offer.
+Open-set Unsupervised Video Domain Adaptation. In the
+realm of action recognition the open-set video domain adapta-
+tion (OUVDA) the literature is relatively under explored. Busto
+et al. (2019) proposed a generic approach based on learning a
+mapping from the source to the target domain and learning an
+open-set classifier on the mapped samples. CEVT was intro-
+duced by Chen et al. (2021) that models the entropy of the tar-
+get samples as generalised extreme value distribution in order
+to perform open-set separation. Differently from the prior art
+CEVT, our proposed approach additionally exploits the tempo-
+ral dynamics in the video sequences. We observe that mod-
+elling the temporal dynamics can lead to better representations,
+which leads to even compact action clusters. Moreover, the
+adopted contrastive learning objective allows us to align the two
+domains without the need of any adversarial feature alignment.
+Contrastive Representation Learning. As collecting anno-
+tated data is costly, the research community has focused on
+self-supervised representation learning (SSL) that learns dis-
+criminative features unsupervisedly with the help of a pretext
+task.
+Contrastive learning (Gutmann and Hyv¨arinen, 2010;
+Chen et al., 2020; He et al., 2020) is one such family of SSL
+methods that casts the learning as an instance discrimination
+task where the similarity between two correlated views are
+maximized. So far in the literature, contrastive learning has re-
+cently been exploited in an attempt to learn discriminative fea-
+tures, but only in the context of closed-set UVDA (Munro and
+Damen, 2020; Kim et al., 2021; Sahoo et al., 2021; Turrisi da
+Costa et al., 2022a,b). Moreover, contrastive learning has found
+to be effective for detecting OOD images samples (Winkens
+et al., 2020). Different from these works, our proposed formu-
+lation of different contrastive losses takes into account the tem-
+poral dimension in video. In our experiments we show that the
+proposed temporal contrastive loss is influential in improving
+over the image-based counterparts.
+3. Methods
+In this work, we propose COLOSEO for addressing the
+Open-set Unsupervised Video Domain Adaptation (OUVDA)
+task. We first formally define OUVDA and then we introduce
+our proposed method.
+Problem Definition and Notations. Let us assume that there
+is a labelled source dataset DS = {(XS
+i , yS
+i )}NS
+i=1 containing NS
+instances, where X ∈ X represents an input and y ∈ Y the cor-
+responding K semantic categories. We also assume that there is
+an unlabelled target dataset DT = {XT
+i }NT
+i=1 of NT instances, con-
+taining the K shared semantic categories of the source dataset
+DS and some additional categories, denoted as target-private
+or unknown classes1, which are absent in the DS. These un-
+known classes are designated as the (K +1)th class. As per stan-
+dard unsupervised domain adaptation assumption, the underly-
+ing marginal probability distributions between the source and
+the target domains differ from each other, i.e., p(XS) � p(XT).
+Under such conditions, the goal in the OUVDA is to learn a
+mapping fθ : X → Y, modelled by a neural network f with
+parameters θ, that can correctly classify the shared instances of
+the DT into the first K classes and all the target-private instances
+into the (K + 1)th class.
+Since we are working with arbitrary-length video sequences,
+during training, we sub-sample frames from each video se-
+quence to form constant-length clips. More formally, each in-
+put sample X ∈ X is given as X = {xk}M
+k=1, where M denotes
+the number of frames used in constructing the clip. As it is
+done typically in the action recognition pipelines, c clips from
+a video sequence are presented as input to fθ and then later sum-
+marized (or aggregated) to provide the final class prediction.
+Overview. In this work we propose to simplify the OUVDA
+task by resorting to contrastive learning (Chen et al., 2020; He
+et al., 2020). We choose contrastive learning because it learns
+very discriminative representations that are often useful for sev-
+eral downstream tasks (Ericsson et al., 2021). Moreover, it has
+also been shown in the work by Saito et al. (2020) that learn-
+ing discriminative representations greatly alleviates the mis-
+alignment problem between the shared and unknown classes
+owing to the well-structured feature space. Furthermore, self-
+supervised representation learning has been found useful for de-
+tecting OOD samples (Hendrycks et al., 2019), which is also a
+key constituent challenge in the OUVDA.
+Our proposed COLOSEO is divided into two stages. In the
+first stage, we aim at learning useful video-level feature repre-
+sentations on both the source and the target data such that in-
+stances with the same underlying action are clustered together,
+facilitating the adaptation phase. Since the source data is la-
+belled we use both the standard cross-entropy classification loss
+and the supervised contrastive loss (Sup-Con) (Khosla et al.,
+2020), such that instances from the same class are pulled closer
+to each other, while instances from different class are pushed
+apart. As the target data lack labels, we adopt the augmentation-
+based SimCLR (Chen et al., 2020) loss to cluster the instances
+in the target domain. Lastly, as temporal dynamics are crucial
+for distinguishing between different actions, we propose a tem-
+poral contrastive loss that contrasts between non-shuffled and
+shuffled clips in a given video sequence. The temporal con-
+trastive loss allows the network to learn the salient temporal
+dynamics in an action, which is important for the recognition
+of the action (see Fig. 2 left).
+The second stage deals with further aligning the feature rep-
+resentations of the source and target domains, while ensuring
+that the target-private instances are not aligned with the shared
+classes. To this end, we introduce a simple score-based nearest
+prototype classifier which determines if a target sample belongs
+1In this work target-private and unknown classes are used interchangeably
+
+4
+Augmentation
+Source
+Feature extractor
+Clip 
+1
+Recognizing 
+the Open-set
+Actions
+Target
+Clip-level 
+features
+class 1
+shuffle(    )
+pull
+unknown 
+class
+class 2
+class 1
+class 2
+Source 
+samples
+Target  
+samples
+push
+COLOSEO
+framework
+Clip 
+aggr.
+Clip 
+2
+Clip 
+3
+Clip 
+1
+Clip 
+2
+Clip 
+3
+1
+2
+3
+1
+2
+3
+Projection 
+head
+3
+1
+2
+        shuffle
+1
+3
+2
+shuffle
+class
+ prototype
+Action classifier
+Fig. 2: Overview of our proposed COLOSEO framework. Left: The video sequences are divided into clips, which are input to the feature extractor Φ to obtain
+clip-level features. The clip-level features are then aggregated into the final video-level features h by the clip aggregator network κ(·). We have a projection head
+g(·) that projects the features h to a hypersphere, producing z. The four instantiations of the contrastive losses: Lsup, Laug, Lcross and Ltemp are used to learn
+compact and discriminative features. A well-clustered feature space enables easy separation between the shared and unknown classes. The Lopen is used to learn a
+(K + 1)-way classifier C′ for the target samples. Right: A cosine similarity-based nearest class-prototype metric determines if a target sample belongs to the shared
+classes or not, where γ is used as threshold.
+to the shared classes or not. This score is measured with re-
+spect to the source prototypes (or class centroids) in order to be
+less prone to noisy outliers (see Fig. 2 right). If a target sam-
+ple is deemed to belong to one of the shared classes, we find
+its pseudo-label with the help of the closed-set source classifier
+and employ the Sup-Con loss to align the source and the tar-
+get representations. On the other hand, if the target sample is
+detected to be far from all the source prototypes, it is then ex-
+cluded from the cross-domain feature alignment. A (K+1)-way
+classifier is learned in the second stage that additionally classi-
+fies the detected target-private instances into the (K +1)th class.
+An overview of our method is provided in the Fig. 2, and we
+describe it in detail below.
+3.1. COLOSEO: Contrastive Learning for OUVDA
+To address the OUVDA, we employ contrastive learn-
+ing (Chen et al., 2020; He et al., 2020) in both the stages to
+(i) produce discriminative feature representations for both the
+source and target data; and (ii) align the source and target do-
+mains over the shared classes. We realize the above goals by
+using four different versions of the contrastive losses that dif-
+fer in a way the positives and negatives are created, which
+are: (i) the label-based Sup-Con (Khosla et al., 2020) Lsup,
+where positives consist of samples with the same class label
+and negatives are the samples with a different class label; (ii)
+the augmentation-based contrastive loss Laug where the posi-
+tives are the augmented views of a given sample, and negatives
+consist of all other samples in the mini-batch; (iii) the tempo-
+ral contrastive loss Ltemp where the positives are the same as
+in the augmentation-based Laug loss, but the negatives are cre-
+ated by shuffling the order of the clips of the same video; and
+(iv) the cross-domain contrastive loss Lcross which is similar to
+the Lsup, except that the pseudo-labels are utilized for the unla-
+belled target samples.
+Given a mini-batch of source domain video sequences BS =
+{(XS
+i , yS
+i )}b
+i=1 and target domain video sequences BT = {XT
+i }b
+i=1
+of size b, we apply two stochastic data augmentation transfor-
+mations t(·) and ˜t(·) on each sample to create the positive pairs
+(or views) as (XS
+i , ˜XS
+i ) and (XT
+i , ˜XT
+i ). As each video sequence
+X consists of c clips, we first forward the clips through the fea-
+ture extractor Φ(·) to obtain c clip-level features, which are then
+fused using the clip aggregator network κ(·). In detail, for ev-
+ery input video sequence Xi the aggregator network κ(·) yields
+a video-level feature hi = κ(Φ(Xi)) ∈ R1024. Thus, correspond-
+ing to the positive pairs (XS
+i , ˜XS
+i ) and (XT
+i , ˜XT
+i ) in the input
+space we have (hS
+i , ˜hS) and (hT, ˜hT) in the video-level feature
+space R1024. Following, the previous works on self-supervised
+learning (Chen et al., 2020; Khosla et al., 2020), we also use a
+non-linear projection head g(·) that operates on the video-level
+features producing z = g(h).
+Label-based Contrastive Loss. Since the source data is an-
+notated, we exploit the class label information to create more
+informative positives and negatives.
+In detail, given an in-
+stance XS
+i belonging to the class yS
+i , another instance XS
+j is a
+positive in the mini-batch if it shares the same class label, i.e.,
+yS
+i = yS
+j. Similarly, all other instances in the mini-batch which
+do not share the same class label with XS
+i are considered neg-
+atives. The label-based contrastive loss is then defined, for the
+ith source sample, as:
+Lsup
+i
+= − log
+2b
+�
+j=1
+1yS
+i =yS
+j exp(
+sim(¯zS
+i ,¯zS
+j)
+τ
+)
+exp(
+sim(¯zS
+i ,¯zS
+j)
+τ
+)+
+2b
+�
+k=1
+1k�i1yS
+k�yS
+i exp(
+sim(¯zS
+i , ¯zS
+k)
+τ
+)
+,
+(1)
+where ¯zS = zS ∪ ˜zS, sim(u, v) =
+u⊺v
+∥u∥∥v∥ is the dot product
+between the L2 normalized u and v and τ is a temperature pa-
+rameter. The operator 1k�i evaluates to 1 with k � i or 0 other-
+
+5
+wise. Similarly, the operator 1yS
+k�yS
+i yields 1 if the class labels
+are different, or 0 otherwise.
+Augmentation-based Contrastive Loss. For the unlabelled
+target data, we use the augmentation-based contrastive loss.
+Given an instance i, its positive is defined as the augmented
+view of itself and its negatives are all the other instances in the
+mini-batch. We can define the augmentation-based contrastive
+loss on the ith target sample as:
+Laug
+i
+= − log
+exp(
+sim(zT
+i ,˜zT
+i )
+τ
+)
+�2b
+k=1 1k�i exp(
+sim(zT
+i ,zT
+k)
+τ
+)
+.
+(2)
+We make the Laug loss symmetric by swapping zT and ˜zT and
+averaging the losses.
+Temporal Contrastive Loss. While the self-supervised con-
+trastive loss is very much potent at modelling the shapes of ob-
+jects in the clips while ignoring the low-level appearance in-
+formation, it still might not be sufficient in the case of action
+recognition due to the temporal dynamics associated with an
+action. Consider an example, where the network must discrim-
+inate between the actions “push-up” and “pull-up”. Since
+both these classes depict humans performing work-out routines,
+the invariances induced by the strong augmentations in the con-
+trastive loss would favour discovering the human shape, which
+is confounding for the two action classes. However, the classes
+“push-up” and “pull-up” inherently exhibit different tem-
+poral dynamics, which are unique of their own. We conjecture
+that, asides from modelling the shape with the contrastive loss,
+capturing the temporal dynamics can lead to even more dis-
+criminative features. Thus, in order to benefit from the tempo-
+ral information inherently conveyed in video data, we design a
+video-oriented temporal contrastive loss that contrasts between
+video sequences with shuffled and non-shuffled clips.
+As before, given a sample Xi, we create its positive view
+˜Xi with the help of a strong augmentation. Whereas, for con-
+trasting with a regular video sequence, we artificially generate
+negatives by randomly permuting the order of clips in Xi, pro-
+ducing X−
+i . However, as the contrastive loss requires a signifi-
+cant amount of negatives in a mini-batch to work (Chen et al.,
+2020; He et al., 2020), one would need perform repeated for-
+ward passes through the clip aggregator network for every per-
+mutation. To circumvent this, we simplified the contrastive for-
+mulation to a triplet loss (Chechik et al., 2010), which achieves
+a similar effect. Then, the goal is to push the anchor Xi close
+to the augmented sequence ˜Xi, while pushing Xi away from the
+shuffled X−
+i (see Fig. 3) in the feature space. The temporal con-
+trastive loss for the ith sample is given as:
+Ltemp
+i
+= max{d(hi, ˜hi) − d(hi, h−
+i ) + α, 0}
+(3)
+where d(·, ·) is a distance function defined as d(·, ·) = || · − · ||2,
+where α indicates the margin of the triplet loss.
+Cross-domain Contrastive Loss. While the aforementioned
+contrastive losses can lead to a well-clustered feature space,
+they do not guarantee that the source and target class clusters
+are perfectly aligned. This is primarily caused by domain shift.
+PUSH
+1
+2
+3
+1
+2
+3
+3
+1
+2
+1
+2
+3
+PULL
+Fig. 3: An overview of the temporal contrastive loss Ltemp. The anchor and pos-
+itive are created with transformations t(·) and ˜t(·), respectively. The negatives
+are artificially generated by shuffling the clips. The Ltemp learns the temporal
+dynamics by pulling the anchor towards the positive, and pushing the negative
+far from the anchor
+To further align the two domains, we propose to use a cross-
+domain contrastive loss that is similar to the label-based con-
+trastive loss Lsup, except that pseudo-labels are used for the un-
+labelled target samples. In particular, to align a target sample
+XT
+i with the source samples, we first infer the pseudo-label ˆyT
+i
+of the ith target sample using the source classifier C(·). Then we
+proceed as in Eq. (1) to define the cross-domain contrastive loss
+as:
+Lcross
+i
+= − log
+2b
+�
+j=1
+1ˆyT
+i =yS
+j exp(
+sim(zT
+i ,zS
+j)
+τ
+)
+exp(
+sim(zT
+i ,zS
+j)
+τ
+)+
+2b
+�
+k=1
+1k�i1yS
+k�ˆyT
+i exp(
+sim(zT
+i , zS
+k)
+τ
+)
+,
+(4)
+While inferring the pseudo-label of a target sample with
+the K-way source classifier C(·) may work seamlessly in the
+closed-set UVDA, it is problematic in the OUVDA case be-
+cause of the presence of the target-private classes.
+To pre-
+vent the target-private classes from being assigned to one of
+the shared categories, we present an unknown class detection
+protocol that eliminates the target samples that are unlikely to
+belong to one of the shared classes. Next we elaborate the un-
+known class detection protocol.
+3.2. Recognizing the Open-set Actions
+Before the pseudo-labels are inferred for the target samples,
+we need a mechanism that can automatically detect the target-
+private classes. For this purpose, we design a metric which
+
+6
+assigns a score to each target sample. A low score means that
+the target sample’s representation is far from the training data,
+and is likely to be a target-private instance. For this purpose, we
+use cosine similarity as the metric between the target feature hT
+i
+and the nearest source class prototype. The class prototype µk
+for a source class k is obtained by averaging the features of all
+the training samples of class k, which is defined as:
+µk = 1
+NS
+k
+NS
+k
+�
+i=1
+κ(Φ(XS
+i ))
+(5)
+where NS
+k is the number of source samples from the class k.
+If the target feature hT
+i is farther than its nearest source class
+prototype µk by a threshold γ, i.e., it has cosine similarity lower
+than the γ, we consider this sample as target-private. Thus, we
+have an indicator variable s which is 1 if a target sample XT
+i is
+target-private and 0 otherwise. We can define it formally as:
+si = 1
+�
+maxk∈{1,2,...,K}(sim(hT
+i , µk)) ≤ γ
+�
+(6)
+where all the target samples with s = 1 are not included in the
+cross-domain contrastive loss Lcross.
+Since the final goal in the OUVDA is not only to classify
+the shared target instances into one of the K classes but also to
+classify all the target-private instances into the (K + 1)th class,
+we initialize a (K + 1)-way classifier C′(·) in the second stage
+of training. All the target samples where s = 1 using Eq. (6)
+are assigned an “unknown” label K + 1. We then use a standard
+cross-entropy loss to assign a high likelihood to the target pri-
+vate instances to be belonging to the (K + 1)th class. Whereas,
+for the source samples we keep the standard classification loss.
+The cross-entropy loss is for a source XS
+i and target-private in-
+stance XT
+i,s=1 is defined as:
+Lopen
+i
+= −
+1
+K + 1
+K+1
+�
+j=1
+yi,j log ψ(C′(κ(Φ(Xi))))
+(7)
+where ψ(·) is the softmax function for normalizing the network
+logits into a probability distribution. Note that in Eq. (7), for
+a target-private instance XT
+i,s=1, we backpropagate only for the
+(K + 1)th class.
+Overall objective. We train our model with a mini-batch using
+the following final objective:
+L = Lopen + Lsup + Laug + Lcross + λLtemp
+(8)
+where λ is a weight for the temporal contrastive loss.
+Inference. During inference the classifier C′(·) is used for clas-
+sifying the target samples into one of the known or the unknown
+(K + 1)th category.
+4. Experiments
+4.1. Experimental Set-up
+Benchmarks. We evaluate our proposed framework under
+the OUVDA task on four benchmarks that are derived from
+UCF101 (Soomro et al., 2012), HMDB (Kuehne et al.,
+2011), Olympic Sports (Niebles et al., 2010) and Epic
+Kitchens (Damen et al., 2018) action recognition datasets. The
+four benchmarks are described below.
+The HMDB↔UCF (Chen et al., 2021) benchmark is con-
+structed by collecting the 12 overlapping categories, viz.,
+Climb, Fencing, Golf, Kick Ball, Pull-up, Punch,
+Push-up,
+Ride Bike,
+Ride Horse,
+Shoot Ball,
+Shoot Bow and Walk, present in the HMDB and UCF-101
+datasets. Out of these 12 classes, the first six of them are se-
+lected as shared classes and the remaining six as target-private
+classes.
+Similarly, the UCF↔Olympic benchmark contains
+six overlapping categories, viz., Basketball, Clean and
+Jerk, Diving, Pole Vault, Tennis and Discus
+Throw, from the UCF-101 and the Olympic Sports datasets,
+where the first half are shared classes and the rest are target-
+private ones. For both of these two benchmarks we follow the
+splits proposed in the CEVT (Chen et al., 2021).
+Given saturated performance on the above benchmarks, we
+also consider the benchmarks which is constructed from the
+egocentric action recognition dataset Epic Kitchens (EK). The
+original EK dataset is composed of first-person video sequences
+depicting egocentric actions (e.g.“insert”, “mix”, etc.) per-
+formed in various kitchen environments, with a total of 32 en-
+vironments. The closed-set UVDA work MM-SADA Munro
+and Damen (2020) introduced a UVDA benchmark with three
+kitchens P01, P22 and P08 from the EK as the three domains
+D1, D2 and D3, respectively, with eight action classes (viz.,
+Put, Take, Open, Close, Wash, Cut, Mix, Pour) over-
+lapping among them. We adapt these three domains as a bench-
+mark for the OUVDA by additionally including all the instances
+from the non-overlapping classes of the target domain as target-
+private.
+Evaluation metrics. To compare our proposed COLOSEO to
+the baselines we adopt the metrics reported in the recent OU-
+VDA work CEVT (Chen et al., 2021). Specifically, we report:
+the ALL (or the K+1 way) accuracy that is the percentage of
+correctly predicted target samples over all the target samples;
+the OS∗ is the averaged class accuracy over the known classes
+only; the UNK recall metric which denotes the ratio of correctly
+predicted “unknown” target instances over the total number of
+“unknown” instances; and the HOS =
+OS∗×UNK
+OS∗+UNK which is the
+harmonic mean between the known OS∗ and unknown UNK
+accuracy. The HOS is the preferred metric in the open-set liter-
+ature (Bucci et al., 2020; Saito and Saenko, 2021) because the
+model can classify all the target instances to “unknown” class
+and attain 100% UNK accuracy but 0% OS∗ accuracy. Thus,
+in order to have a high HOS score the model must do well in
+both the OS∗ and the UNK metrics. Note that the CEVT also
+reports OS, the open-set average accuracy over the classes, but
+is similar to the ALL accuracy in nature. Being redundant, we
+do not report the OS accuracy.
+Implementation details. We use the I3D architecture as back-
+bone, pretrained on Kinetics-400 as provided by Carreira and
+Zisserman (2017). We input c = 3 clip-level features, each
+of dimension 1024 to the aggregation module κ, which out-
+puts a 1024 dimensional feature h. Both the projection head
+
+7
+Method
+Backbone
+HMDB→UCF
+UCF→HMDB
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+DANN (Ganin et al., 2015) + OSVM (Jain et al., 2014)
+ResNet101
+64.6
+62.9
+74.7
+68.3
+66.1
+48.3
+83.9
+61.3
+JAN (Long et al., 2016) + OSVM (Jain et al., 2014)
+61.5
+62.9
+73.8
+67.9
+61.1
+47.8
+74.4
+58.2
+AdaBN (Li et al., 2018) + OSVM (Jain et al., 2014)
+62.9
+58.8
+73.3
+65.3
+62.9
+58.8
+73.3
+65.3
+MCD (Saito et al., 2018a) + OSVM (Jain et al., 2014)
+66.7
+63.5
+73.8
+68.3
+66.7
+57.8
+75.6
+65.5
+TA2N (Chen et al., 2019) + OSVM (Jain et al., 2014)
+63.4
+61.3
+79.0
+69.1
+65.3
+56.1
+74.4
+64.0
+TA3N (Chen et al., 2019) + OSVM (Jain et al., 2014)
+60.6
+58.4
+82.5
+68.4
+62.2
+53.3
+71.7
+61.2
+OSBP (Saito et al., 2018b) + AvgPool
+64.8
+55.3
+85.7
+67.2
+67.2
+50.8
+84.5
+63.5
+CEVT (Chen et al., 2021)
+70.6
+66.8
+84.3
+74.5
+75.3
+56.1
+94.5
+70.4
+OVANet (Saito and Saenko, 2021)
+I3D
+80.8
+90.4
+76.0
+82.6
+70.6
+67.0
+71.4
+69.6
+CEVT (Chen et al., 2021)
+67.6
+59.7
+93.0
+72.7
+80.1
+60.3
+96.1
+74.1
+COLOSEO-E (ours)
+79.3
+87.5
+80.8
+84.0
+82.2
+80.6
+84.4
+82.5
+COLOSEO (ours)
+78.3
+81.1
+88.7
+84.7
+89.1
+76.7
+98.9
+86.4
+Table 1: Comparison with the state-of-the-art performance on the HMDB↔UCF benchmark. Best and second best numbers are highlighted in bold and underlines,
+respectively. The numbers of methods using ResNet101 as backbone are taken from Chen et al. (2021). Overall, our proposed COLOSEO outperforms the
+state-of-the-art methods in terms of the important HOS metric
+Method
+Backbone
+UCF→Olympic
+Olympic→UCF
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+DANN (Ganin et al., 2015) + OSVM (Jain et al., 2014)
+ResNet101
+94.4
+96.7
+91.3
+93.9
+83.3
+86.4
+80.6
+83.4
+JAN (Long et al., 2016) + OSVM (Jain et al., 2014)
+94.4
+100.0
+87.0
+93.0
+88.7
+80.5
+95.5
+87.3
+AdaBN (Li et al., 2018) + OSVM (Jain et al., 2014)
+87.0
+78.5
+100.0
+87.9
+84.1
+76.9
+89.5
+82.8
+MCD (Saito et al., 2018a) + OSVM (Jain et al., 2014)
+87.0
+86.7
+87.0
+86.8
+83.7
+85.5
+82.1
+83.8
+TA2N (Chen et al., 2019) + OSVM (Jain et al., 2014)
+96.3
+100.0
+91.3
+95.4
+87.9
+78.5
+95.5
+86.2
+TA3N (Chen et al., 2019) + OSVM (Jain et al., 2014)
+88.9
+87.9
+91.0
+89.6
+85.8
+85.6
+85.8
+85.7
+OSBP (Saito et al., 2018b) + AvgPool
+96.9
+94.4
+100.0
+97.1
+89.0
+84.3
+92.0
+88.0
+CEVT (Chen et al., 2021)
+98.1
+97.0
+100.0
+98.5
+89.2
+86.4
+91.0
+88.7
+OVANet (Saito and Saenko, 2021)
+I3D
+80.8
+90.4
+76.0
+82.6
+70.6
+67.0
+71.4
+69.6
+CEVT (Chen et al., 2021)
+81.4
+67.2
+100.0
+80.4
+90.8
+84.3
+96.2
+89.9
+COLOSEO-E (ours)
+92.8
+100.0
+100.0
+100.0
+84.1
+95.8
+76.4
+85.0
+COLOSEO (ours)
+98.2
+100.0
+95.0
+97.4
+90.8
+86.7
+94.0
+90.7
+Table 2: Comparison to the state-of-the-art performance on the UCF↔Olympic benchmark. Overall, our proposed COLOSEO outperforms several state-of-the-art
+methods in terms of the HOS score. Best and second best numbers are highlighted in bold and underlines, respectively. The numbers of methods using ResNet101
+as backbone are taken from Chen et al. (2021). Note that this benchmark is smaller with only three shared and three unknown categories, and thus results have
+mostly saturated
+g(·) and κ(·) modules are implemented as a 2-layer MLP net-
+work. The classifiers C and C′ are implemented as linear lay-
+ers, with input 1024 (video-level feature) and output equal to
+K and K + 1, respectively. In both the stages we trained our
+network with an SGD optimizer having momentum as 0.9, and
+learning rates 0.01 for the HMDB↔UCF and UCF↔Olympic,
+whereas 0.001 for the Epic-Kitchens. We use batch size equal
+to 16 for all settings, and the parameter α was kept at the de-
+fault value of 1. Our code is publicly available at https:
+//github.com/gzaraunitn/COLOSEO.
+Baselines. We adopt the baselines from Chen et al. (2021),
+most of which are closed-set UDA methods adapted to the
+open-set scenario using OSVM (Jain et al., 2014).
+In de-
+tails, we report DANN (Ganin et al., 2015), JAN (Long
+et al., 2016), AdaBN (Li et al., 2018), MCD (Saito et al.,
+2018a), OSBP (Saito et al., 2018b) and video-oriented TA2N,
+TA3N (Chen et al., 2019) and CEVT (Chen et al., 2021).
+Moreover, we compare with an image-based OUDA method
+OVANet (Saito and Saenko, 2021), which we re-purposed
+to make it video-oriented.
+We additionally compare to the
+CEVT (Chen et al., 2021) that uses the I3D backbone (Car-
+reira and Zisserman, 2017), instead of the original Resnet-101,
+for a fair comparison.
+Finally,
+we also consider a variant of our proposed
+COLOSEO, where the target-private rejection is carried out
+by thresholding the entropy computed by the closed-set classi-
+fier C(·), instead of using the source prototypes as described in
+Sec. 3. We call this variant as the COLOSEO-E. Through our
+experiments we demonstrate that this entropy-based variant is
+often suboptimal with respect to our final method COLOSEO.
+4.2. Comparison to the State of the Art
+We report in the Tab. 1, 2 and 3 the results obtained on
+the HMDB↔UCF, UCF↔Olympic and Epic-Kitchens bench-
+marks, respectively. Overall, we observe from these tables that
+our proposed COLOSEO outperforms the competitors in 8/10
+adaptation settings in terms of the all important HOS metric.
+In details, from the Tab.
+1 we can see that for the
+UCF→HMDB adaptation setting our proposed COLOSEO
+yields the best UNK and HOS metrics, and the second best
+closed-set accuracy denoted by OS∗. In addition, COLOSEO
+achieves the best score for the ALL metric as well. On the
+other hand, for the reverse adaptation setting HMDB→UCF,
+although our COLOSEO does not outperform the competitors
+in individual metrics, it surpasses them in terms of the HOS, by
+obtaining a better balance between OS∗ and UNK. On the con-
+trary, we can observe that several competitors fail to maintain a
+good trade-off between the OS∗ and UNK, achieving a higher
+
+8
+Method ↓
+Setting →
+D2→D1
+D3→D1
+D1→D2
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+CEVT (Chen et al., 2021)
+27.8
+6.2
+65.7
+11.3
+32.3
+4.2
+93.6
+8.0
+18.9
+5.4
+85.1
+10.2
+OVANet (Saito and Saenko, 2021)
+29.2
+18.8
+45.8
+26.7
+35.6
+22.3
+42.5
+29.3
+23.9
+16.0
+45.9
+23.7
+COLOSEO-E (ours)
+36.3
+22.4
+70.8
+34.0
+32.4
+11.7
+72.9
+20.2
+23.8
+17.0
+88.2
+28.5
+COLOSEO (ours)
+38.8
+24.8
+60.4
+35.2
+33.1
+21.8
+60.4
+32.0
+28.3
+25.4
+64.7
+36.5
+Method ↓
+Setting →
+D3→D2
+D1→D3
+D2→D3
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+CEVT (Chen et al., 2021)
+21.9
+10.4
+96.3
+18.8
+21.3
+4.2
+70.7
+7.9
+25.3
+6.6
+83.9
+12.2
+OVANet (Saito and Saenko, 2021)
+30.8
+31.4
+31.8
+31.6
+28.5
+15.9
+35.9
+22.0
+34.0
+16.7
+50.0
+25.0
+COLOSEO-E (ours)
+28.8
+25.6
+70.5
+37.6
+25.9
+10.9
+70.3
+18.9
+30.8
+22.6
+56.2
+32.2
+COLOSEO (ours)
+33.3
+34.3
+47.0
+39.7
+34.4
+24.9
+39.0
+30.4
+32.1
+17.6
+40.2
+24.5
+Table 3: Comparison to the state-of-the-art performance on the Epic-Kitchens benchmark (with domains as D1, D2 and D3). All the methods use I3D as backbone.
+Best and second best numbers are highlighted in bold and underlines, respectively. Overall, our proposed COLOSEO-E and COLOSEO outperform the existing
+state-of-the-art methods in terms of the HOS score.
+value in one or the other metric, but at the cost of a severe drop
+in the other one, resulting in a lower overall HOS.
+As for UCF↔Olympic benchmark, it is worth noting that
+the benchmark is very small (composed of only three known
+and three unknown classes) and has saturated performance.
+Nonetheless, we can observe in the Tab. 2 that COLOSEO
+has competitive or better HOS scores when compared to
+its competitors.
+In particular, in the Olympic→UCF setting
+COLOSEO achieves the best HOS score, whereas in the re-
+verse direction our other variant COLOSEO-E outperforms ev-
+ery method.
+In the Tab. 3 we report the results for the challenging Epic-
+Kitchens (EK) benchmark. For the EK benchmark we com-
+pare our proposed method with two existing state-of-the-art
+image-based OVANet and video-based CEVT methods. From
+a first glance we notice that the overall scores in the Tab. 3 is
+lower as compared to the HMDB↔UCF and UCF↔Olympic
+benchmarks.
+This can be attributed to: the challenging na-
+ture of the first-person (egocentric) actions performed in clut-
+tered indoor kitchen environments; and the mismatch of the
+I3D pre-training Kinetics dataset containing actions from third-
+person views performed outdoor. Nevertheless, our two vari-
+ants COLOSEO-E and COLOSEO outperforms the existing
+state-of-the-art in several adaptation settings of the EK.
+In particular, the results in the Tab. 3 show that COLOSEO’s
+HOS score generally benefits from a higher closed-set accu-
+racy OS∗ when compared to other methods, although it doesn’t
+achieve the best score with respect to the open-set accuracy
+UNK. Contrary to our proposed method, the competitor method
+CEVT is prone to classifying most of the target instances as
+“unknown”, as evident from high UNK accuracy but very low
+closed-set accuracy OS∗.
+This leads to the CEVT exhibit-
+ing significantly lower HOS scores when compared to our
+COLOSEO-E and COLOSEO.
+4.3. Ablation Analysis
+We report the results of a thorough ablation analysis of
+the COLOSEO framework conducted to better understand
+the impact of the proposed components and the sensitivity of
+COLOSEO to the hyperparameters.
+Method
+ALL
+OS∗
+UNK
+HOS
+Ours w/o Lsup
+74.1
+71.7
+89.4
+79.6
+Ours w/o Laug
+78.1
+85.0
+80.7
+82.8
+Ours w/o Lcross
+74.8
+73.5
+90.0
+80.9
+Ours w/o Ltemp
+74.1
+79.6
+77.1
+78.4
+Ours w/o Lsup, Laug, Lcross
+71.6
+81.1
+73.7
+77.2
+Ours (full)
+78.3
+81.1
+88.7
+84.7
+Table 4: Ablation study of the contrastive losses in our COLOSEO in the
+HMDB→UCF adaptation setting
+Impact of the contrastive losses. First, we analyze the impact
+of the contrastive losses on the performance obtained by the
+proposed COLOSEO. In the Tab. 4 we report the performance
+of COLOSEO for the adaptation setting HMDB→UCF when
+removing the individual contrastive losses described in Sec. 3.
+In details, we ablate by removing Lsup, Ltemp, Lcross and Laug
+one at a time from the final objective in Eq. 8. We can ob-
+serve that all the contrastive losses positively contribute to the
+final score and removing any of them negatively impacts the
+metrics. Notably, the absence of the newly proposed temporal
+contrastive loss Ltemp leads to a significant drop in performance
+(by -6.3% points). This highlights the importance of leveraging
+the temporal information in videos for a well structured repre-
+sentation space, which can be realized for free without needing
+any labels.
+Furthermore, note that even without the cross-domain align-
+ment loss Lcross the performance is relatively high, with a drop
+of only 3.8% points, which is lower than without the Ltemp loss
+(6.3% points drop). It hints at the fact that the Ltemp and Laug
+can effectively and implicitly align the two domains without
+needing any alignment technique.
+Method
+# clips = 3
+# clips = 4
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+COP
+72.5
+73.4
+90.0
+80.8
+53.8
+73.6
+42.1
+53.5
+COLOSEO
+78.3
+81.1
+88.7
+84.7
+67.9
+63.1
+84.7
+72.3
+Table 5: Comparison of the COLOSEO to the COP baseline and the impact of
+the number of clips c in the HMDB→UCF adaptation setting
+
+9
+Method
+HMDB→UCF
+UCF→HMDB
+ALL
+OS∗
+UNK
+HOS
+ALL
+OS∗
+UNK
+HOS
+CEVT (Chen et al., 2021)
+66.7±0.9
+49.9±9.2
+87.2±6.4
+62.8±8.0
+72.6±5.7
+57.7±11.6
+89.2±5.9
+64.1±7.9
+COLOSEO-E (ours)
+83.1±3.8
+79.3±7.4
+87.8±2.5
+83.0±2.8
+81.9±0.4
+74.4±6.3
+94.8±7.3
+82.9±3.1
+COLOSEO (ours)
+83.7±3.8
+80.1±0.8
+90.9±2.5
+85.4±0.5
+83.5±3.9
+74.9±4.2
+93.0±4.6
+82.9±2.9
+Table 6: Comparison of the averaged performance under three different splits of the shared and unknown classes on the HMDB↔UCF benchmark. Each entry
+reports the average and the standard deviation of a metric across three splits. All the methods use I3D as backbone. Best average performance is highlighted in bold.
+Overall, the COLOSEO consistently and substantially outperforms the CEVT, while having lower variance than CEVT in both the adaptation settings.
+0.35
+0.40
+0.45
+0.50
+0
+20
+40
+60
+80
+100
+HOS (in %)
+COLOSEO
+Fig. 4: Impact on the HOS score while varying the threshold value γ, which
+is used for the known/unknown target separation in the COLOSEO, in the
+HMDB→UCF adaptation setting
+Comparison to video-based pretext task. Temporal informa-
+tion offered by video data has previously been exploited in a
+UVDA method SAVA (Choi et al., 2020) that in particular uses
+the clip ordering prediction (COP) as a pretext task. In details,
+the COP consist in training the model to predict the correct or-
+der in which the input clips have been permuted. The key idea is
+that while trying to distinguish between the input clips that are
+temporally shuffled from the non-shuffled (or original) ones,
+the network will learn salient and representative features from
+the actions. Given that our proposed temporal loss Ltemp shares
+similar spirit with the pretext task of COP, we also compare and
+report in Tab. 5 the results obtained with COLOSEO, except by
+replacing Ltemp with the COP loss, for c = 3 and c = 4 clips.
+It is evident from the Tab. 5 that our Ltemp significantly outper-
+forms the COP baseline, which produces much more unstable
+results, with a tendency to either over-accept or over-reject sam-
+ples. Furthermore, when using 4 clips, the COP loss produces
+a drastic drop with respect to the final score, as the ordering
+problem becomes more challenging (being a c!-way classifi-
+cation problem), which aligns with the findings in Choi et al.
+(2020). In contrast to the COP loss, our temporal loss is signif-
+icantly more robust to the increased number of clips, which is
+evident by an increased gap in the HOS scores between the two
+methods.
+Sensitivity to hyperparameters. In the Fig. 4 we demonstrate
+the sensitivity analysis on the hyperparameter γ described in the
+Eq. (6). The γ governs whether to assign a target instance to a
+shared class or reject it as target-private class. The Fig. 4 shows
+that HOS score of our COLOSEO remains fairly stable over a
+wide range of γ values. From our experiments we observe that
+10
+1
+10
+0
+10
+1
+0
+20
+40
+60
+80
+100
+HOS (in %)
+COLOSEO
+Fig. 5: Impact on the HOS score while varying λ, which weights the temporal
+contrastive loss, in the HMDB→UCF adaptation setting. Note that the x-axis is
+in logarithmic scale
+extreme low or high values of γ results in the protocol over-
+accepting and over-rejecting target instances, respectively, thus
+favoring one of the metrics between OS∗ and UNK but impact-
+ing negatively the final HOS score. Thus, we limit the values
+of γ within reasonable limits despite the theoretical bounds of
+γ lies in [0, 1].
+We also ablate on the second hyperparameter λ that con-
+trols the contribution of the temporal contrastive loss Ltemp to
+the final objective described in Eq. 8. Given our implementa-
+tion of the Ltemp, described in Eq. 3, uses a triplet loss instead
+of the traditional InfoNCE contrastive objective (Gutmann and
+Hyv¨arinen, 2010), we had to balance the maginitude of the
+Ltemp. In the Fig. 5 we plot the HOS score by varying the λ
+in logarithmic scale. We can observe that the chosen value in
+the final version of our framework (i.e. λ = 0.1) leads to the
+best HOS score. Furthermore, it emerges that the HOS score
+remains quite stable until λ = 1, and only degrades for very
+large values (λ = 10), which is a reasonable behaviour.
+Impact of shared/unknown classes splits. As shown in the
+open-set recognition literature (Vaze et al., 2022), the UNK
+performance relies heavily on the split between the shared and
+OOD classes, it also becomes imperative to test the OUVDA
+methods under different shared/unknown classes splits. To this
+end, we report in Tab. 6 the averaged results obtained by our
+proposed method and compare them to the best competitor
+CEVT under three random splits of 6 shared and 6 unknown
+classes of the HMDB↔UCF benchmark.
+We can see that
+our COLOSEO and COLOSEO-E outperforms the CEVT
+by significant margins even under different different splits of
+the shared and unknown classes. More interestingly, the stan-
+
+10
+dard deviation in the HOS score attained by our COLOSEO is
+also substantially lower than that of CEVT (0.5 versus 8.0 and
+2.9 versus 7.9 in the HMDB→UCF and UCF→HMDB adapta-
+tion settings, respectively). This shows that irrespective of the
+shared action categories present in the source, the representa-
+tion space learned by COLOSEO is more compact and thereby
+rejecting unknown classes becomes easier than the weighted
+adversarial strategy used in the CEVT.
+0
+10
+20
+30
+40
+50
+Epoch
+56
+58
+60
+62
+64
+66
+68
+ALL (in %)
+COLOSEO
+Fig. 6: The evolution of the pseudo-label ALL accuracy of COLOSEO on the
+target domain with the progression of training in the HMDB→UCF adaptation
+setting
+Quality of pseudo-labels. Given our cross-domain contrastive
+loss Lcross in the Eq. 4 relies on the pseudo-labels computed
+on the target, in Fig. 6 we visualize the ALL accuracy metric
+of the pseudo-labels for the HMDB→UCF adaptation setting,
+as the training progresses. As expected, we observe that ALL
+pseudo-label accuracy on the target training data is increasing
+as the training progresses. This in turn positively impacts the
+Lcross to better align the source and the shared target classes.
+Moreover, as the ALL also includes the accuracy of the un-
+known class prediction, it also indirectly reflects the usefulness
+of the unknown target rejection.
+5. Conclusions
+In this work we presented the COLOSEO framework for
+addressing open-set unsupervised video domain adaptation.
+Our proposed COLOSEO leverages contrastive learning under
+complementary yet unified formulations to: (i) learn discrim-
+inative and compact feature representations in both the source
+and target domains; and (ii) align source and target distributions
+with respect to the shared classes. In particular, the COLOSEO
+includes a video oriented temporal contrastive loss that clusters
+different actions by exploiting the temporal information avail-
+able freely in video data. We showed that learning compact
+representations can simplify the separation between the shared
+and unknown classes. We carried out an extensive experimental
+evaluation on three OUVDA benchmarks and demonstrated that
+our COLOSEO significantly outperforms the existing state-of-
+the-art methods.
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf,len=1237
+page_content='1  Computer Vision and Image Understanding  journal homepage: www.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='elsevier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='com  Simplifying Open-Set Video Domain Adaptation with Contrastive Learning  Giacomo Zaraa, Victor Guilherme Turrisi da Costaa, Subhankar Royb, Paolo Rotaa, Elisa Riccia,b  aUniversity of Trento, Via Sommarive 9, Trento, Italy  bFondazione Bruno Kessler, Via Sommarive 18, Trento, Italy  ABSTRACT  In an effort to reduce annotation costs in action recognition, unsupervised video domain adaptation  methods have been proposed that aim to adapt a predictive model from a labelled dataset (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', source  domain) to an unlabelled dataset (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', target domain).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In this work we address a more realistic scenario,  called open-set video domain adaptation (OUVDA), where the target dataset contains “unknown”  semantic categories that are not shared with the source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The challenge lies in aligning the shared  classes of the two domains while separating the shared classes from the unknown ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In this work we  propose to address OUVDA with an unified contrastive learning framework that learns discriminative  and well-clustered features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We also propose a video-oriented temporal contrastive loss that enables  our method to better cluster the feature space by exploiting the freely available temporal information  in video data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We show that discriminative feature space facilitates better separation of the unknown  classes, and thereby allows us to use a simple similarity based score to identify them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We conduct  thorough experimental evaluation on multiple OUVDA benchmarks and show the effectiveness of our  proposed method against the prior art.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  © 2023 Elsevier Ltd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' All rights reserved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Introduction  Action recognition is an important problem in the field of  computer vision where the task consists in recognizing the ac-  tion being performed in a video sequence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Supervised action  recognition (Tran et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Feichtenhofer et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2016;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Car-  reira and Zisserman, 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Zhou et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2018) is widely stud-  ied because of the growing need for automatically categorizing  video content that are being generated everyday.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' However, it is  nearly impossible for human annotators to keep pace with the  enormous volumes of online videos, and thus supervised train-  ing becomes infeasible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A cheaper way of leveraging the mas-  sive pool of unlabelled data is by exploiting an already trained  model to infer the labels on such data and then re-using them  to build an improved model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Such an approach is also prone  to failure because the unlabelled data may belong to a data dis-  tribution that is different from the annotated one, which is of-  ten referred to as the domain-shift problem (Torralba and Efros,  2011).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  To address the domain-shift problem, Unsupervised Video  Domain Adaptation (UVDA) methods (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2019;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Choi  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Pan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) have been proposed that aim  to learn a model for the domain of interest by jointly lever-  aging the annotated source data and the unannotated target  data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  However, these methods make a strong and unrealis-  tic assumption that the source and target domains share the  same label space, which is also known as the closed-set sce-  nario.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The closed-set assumption is rarely the case in the real  world as the target domain can contain video sequences from  action categories that are not present in the source dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Such  non-overlapping categories are known as the out-of-distribution  (OOD) classes (Vaze et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A naive application of the  existing UVDA techniques will cause the model to incorrectly  classify the OOD classes as one of the shared ones, which is  undesirable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Due to the limited applicability of the closed-set UVDA set-  ting, the focus has been shifting towards the more challeng-  ing open-set scenario where the target dataset contains samples  associated with categories that are not present in the source do-  main.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In the context of action recognition, this task is referred to  as the Open-Set Unsupervised Video Domain Adaptation (OU-  VDA) (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The main goal in OUVDA consists in  adapting a model to the target domain that can align the classes  that are shared between the two domains while excluding the  OOD (also known as target-private or unknown) classes from  the alignment process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Although open-set unsupervised domain  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='03322v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='CV]  9 Jan 2023  ELSEVLER2  adaptation has received significant attention for the image clas-  sification task (Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2018b, 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Bucci et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Saito and Saenko, 2021;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Bucci et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021), it is rather under-  studied in the field of action recognition (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  The recently proposed OUVDA method, CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  2021), uses a weighted adversarial learning strategy, with the  weights derived from class-conditional extreme value theory,  in order to recognize the target-private classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' However, ad-  versarial learning-based alignment can be unstable in practice,  especially in the open-set scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In this work, we argue that  OUVDA can be greatly simplified if we can learn discrimina-  tive features on both the source and target data for the following  two reasons: (i) it can implicitly align the shared classes be-  tween the source and target domains by learning semantically  distinct clusters (Wang and Isola, 2020);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and (ii) it results in  the target-private classes being well separated from the shared  ones (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Based on this intuition, we propose to lever-  age contrastive learning (Gutmann and Hyv¨arinen, 2010;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Chen  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' He et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) to obtain discriminative represen-  tations to tackle OUVDA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In details, we realize the above goals by proposing to use  different instantiations of the contrastive loss that mainly dif-  fer in how the positives and negatives are mined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To recap, the  contrastive loss (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) relies on positives and neg-  atives which are then contrasted to learn feature representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In our proposed method we use four such instantiations of con-  trastive loss: (i) a label-based supervised contrastive loss for  the source;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (ii) an augmentation-based contrastive loss for the  target;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (iii) a cross-domain contrastive loss between the source  and the pseudo-labelled target;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and (iv) a temporal contrastive  loss to learn the temporal dynamics present in video data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' One  important advantage with such a proposal is that we can lever-  age an unique contrastive formulation to unify several losses,  which cater to different learning aspects of the task at hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' It  also ensures compatible gradients and dispose of the need of  tuning several hyperparameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To this end, we call our pro-  posed method COLOSEO (COntrastive Learning for Open-  SEt VideO Domain Adaptation).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Owing to the well-clustered feature space we observe that it  becomes fairly straightforward to separate the target-private in-  stances from the shared ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In this work we use the nearest  class prototypes (Mensink et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2013) with a simple cosine-  similarity metric to exclude the target-private instances from  the alignment process that lie far from all the source classes  prototypes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We extensively validate our proposed method on  multiple benchmarks: (i) HMDB↔UCF and UCF↔Olympic  that contains actions from third-person view;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and (ii) the chal-  lenging first-person (egocentric) Epic-Kitchens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Contributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To summarize, our main contributions are:  (i) the COLOSEO framework, which uses an unified con-  trastive learning formulation to address the task of OUVDA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  We demonstrate that learning compact and discriminative fea-  ture representations can greatly simplify the OUVDA task;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  (ii) a novel video-oriented temporal contrastive loss that im-  proves the OOD robustness, thereby facilitating the task at  hand;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (iii) we advance the state-of-the-art on three standard OU-  VDA benchmarks by non-trivial margins.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  PUSH  PUSH  PULL  "horse riding"  "horse riding"  "shooting bow"  "shooting bow"  source class 1  source class 1  target class 1  target class 2  target private  class prototype  "climb" (unknown)  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 1: An illustration of a feature space learned with contrastive learning in  order to obtain discriminative video features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A well-clustered feature space  simplifies the separation of the shared classes from the out-of-distribution (or  target-private) ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Related Works  Open-set Unsupervised Domain Adaptation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' There exists  a large body of the open-set unsupervised domain adaptation  (OUDA) literature but applied specifically to the image classi-  fication task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' OUDA was first introduced by Panareda Busto  and Gall (2017) and later then addressed in several subsequent  works, which mostly rely either on adversarial learning or clus-  tering approaches.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Most of the initial works (Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2018b;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Shermin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  2021) exploited adversarial learning to detect target-private  samples while aligning features of different domains for the  known categories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Fu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2019) improved the adversarial ob-  jective of Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2018b) by replacing the binary cross en-  tropy loss with a symmetrical Kullback-Leibler distance-based  loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2019) addressed OUDA by training a multi-  binary classifier with source data, alongside domain discrim-  inator, to progressively separate the samples of unknown and  known classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A graph neural network based approach was  proposed by Luo et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2020) that integrates episodic pseudo-  labelling with adversarial learning to tackle the OUDA task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Recently, the adversarial approaches have been replaced by  clustering-based methods (Wang, 2021) that ensure well clus-  tered target space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' For instance, Bucci et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2021) proposed  HyMOS that uses contrastive learning to enforce invariance to  the augmentations obtained via style transfer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' However, Hy-  MOS is tailored for the multi-source OUDA setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Ma et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  (2021) introduced a method for active OUDA that combines  adversarial learning with the clustering non-transferable gra-  dient embedding approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Recently, Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2020) pro-  posed DANCE that uses self-supervision to cluster the target  3  data, followed by detecting the target-private instances based  on the entropy computed by the classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Different to all other  approaches, OVANet (Saito and Saenko, 2021) trains one-vs-all  binary open set classifiers on the source data to detect and re-  ject the unknown samples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A common theme in all these above  methods is that they are have been proposed for images and do  not exploit the temporal information which video data has to  offer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Open-set Unsupervised Video Domain Adaptation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In the  realm of action recognition the open-set video domain adapta-  tion (OUVDA) the literature is relatively under explored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Busto  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2019) proposed a generic approach based on learning a  mapping from the source to the target domain and learning an  open-set classifier on the mapped samples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' CEVT was intro-  duced by Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2021) that models the entropy of the tar-  get samples as generalised extreme value distribution in order  to perform open-set separation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Differently from the prior art  CEVT, our proposed approach additionally exploits the tempo-  ral dynamics in the video sequences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We observe that mod-  elling the temporal dynamics can lead to better representations,  which leads to even compact action clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Moreover, the  adopted contrastive learning objective allows us to align the two  domains without the need of any adversarial feature alignment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Contrastive Representation Learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As collecting anno-  tated data is costly, the research community has focused on  self-supervised representation learning (SSL) that learns dis-  criminative features unsupervisedly with the help of a pretext  task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Contrastive learning (Gutmann and Hyv¨arinen, 2010;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' He et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) is one such family of SSL  methods that casts the learning as an instance discrimination  task where the similarity between two correlated views are  maximized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' So far in the literature, contrastive learning has re-  cently been exploited in an attempt to learn discriminative fea-  tures, but only in the context of closed-set UVDA (Munro and  Damen, 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Kim et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Sahoo et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Turrisi da  Costa et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2022a,b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Moreover, contrastive learning has found  to be effective for detecting OOD images samples (Winkens  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Different from these works, our proposed formu-  lation of different contrastive losses takes into account the tem-  poral dimension in video.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In our experiments we show that the  proposed temporal contrastive loss is influential in improving  over the image-based counterparts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Methods  In this work, we propose COLOSEO for addressing the  Open-set Unsupervised Video Domain Adaptation (OUVDA)  task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We first formally define OUVDA and then we introduce  our proposed method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Problem Definition and Notations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Let us assume that there  is a labelled source dataset DS = {(XS  i , yS  i )}NS  i=1 containing NS  instances, where X ∈ X represents an input and y ∈ Y the cor-  responding K semantic categories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We also assume that there is  an unlabelled target dataset DT = {XT  i }NT  i=1 of NT instances, con-  taining the K shared semantic categories of the source dataset  DS and some additional categories, denoted as target-private  or unknown classes1, which are absent in the DS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' These un-  known classes are designated as the (K +1)th class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As per stan-  dard unsupervised domain adaptation assumption, the underly-  ing marginal probability distributions between the source and  the target domains differ from each other, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', p(XS) � p(XT).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Under such conditions, the goal in the OUVDA is to learn a  mapping fθ : X → Y, modelled by a neural network f with  parameters θ, that can correctly classify the shared instances of  the DT into the first K classes and all the target-private instances  into the (K + 1)th class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Since we are working with arbitrary-length video sequences,  during training, we sub-sample frames from each video se-  quence to form constant-length clips.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' More formally, each in-  put sample X ∈ X is given as X = {xk}M  k=1, where M denotes  the number of frames used in constructing the clip.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As it is  done typically in the action recognition pipelines, c clips from  a video sequence are presented as input to fθ and then later sum-  marized (or aggregated) to provide the final class prediction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Overview.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In this work we propose to simplify the OUVDA  task by resorting to contrastive learning (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' He  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We choose contrastive learning because it learns  very discriminative representations that are often useful for sev-  eral downstream tasks (Ericsson et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Moreover, it has  also been shown in the work by Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2020) that learn-  ing discriminative representations greatly alleviates the mis-  alignment problem between the shared and unknown classes  owing to the well-structured feature space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Furthermore, self-  supervised representation learning has been found useful for de-  tecting OOD samples (Hendrycks et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2019), which is also a  key constituent challenge in the OUVDA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Our proposed COLOSEO is divided into two stages.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In the  first stage, we aim at learning useful video-level feature repre-  sentations on both the source and the target data such that in-  stances with the same underlying action are clustered together,  facilitating the adaptation phase.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Since the source data is la-  belled we use both the standard cross-entropy classification loss  and the supervised contrastive loss (Sup-Con) (Khosla et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  2020), such that instances from the same class are pulled closer  to each other, while instances from different class are pushed  apart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As the target data lack labels, we adopt the augmentation-  based SimCLR (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) loss to cluster the instances  in the target domain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Lastly, as temporal dynamics are crucial  for distinguishing between different actions, we propose a tem-  poral contrastive loss that contrasts between non-shuffled and  shuffled clips in a given video sequence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The temporal con-  trastive loss allows the network to learn the salient temporal  dynamics in an action, which is important for the recognition  of the action (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 2 left).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  The second stage deals with further aligning the feature rep-  resentations of the source and target domains, while ensuring  that the target-private instances are not aligned with the shared  classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To this end, we introduce a simple score-based nearest  prototype classifier which determines if a target sample belongs  1In this work target-private and unknown classes are used interchangeably  4  Augmentation  Source  Feature extractor  Clip  1  Recognizing  the Open-set  Actions  Target  Clip-level  features  class 1  shuffle(    )  pull  unknown  class  class 2  class 1  class 2  Source  samples  Target  samples  push  COLOSEO  framework  Clip  aggr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Clip  2  Clip  3  Clip  1  Clip  2  Clip  3  1  2  3  1  2  3  Projection  head  3  1  2  shuffle  1  3  2  shuffle  class  prototype  Action classifier  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 2: Overview of our proposed COLOSEO framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Left: The video sequences are divided into clips, which are input to the feature extractor Φ to obtain  clip-level features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The clip-level features are then aggregated into the final video-level features h by the clip aggregator network κ(·).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We have a projection head  g(·) that projects the features h to a hypersphere, producing z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The four instantiations of the contrastive losses: Lsup, Laug, Lcross and Ltemp are used to learn  compact and discriminative features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A well-clustered feature space enables easy separation between the shared and unknown classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The Lopen is used to learn a  (K + 1)-way classifier C′ for the target samples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Right: A cosine similarity-based nearest class-prototype metric determines if a target sample belongs to the shared  classes or not, where γ is used as threshold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  to the shared classes or not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' This score is measured with re-  spect to the source prototypes (or class centroids) in order to be  less prone to noisy outliers (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 2 right).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' If a target sam-  ple is deemed to belong to one of the shared classes, we find  its pseudo-label with the help of the closed-set source classifier  and employ the Sup-Con loss to align the source and the tar-  get representations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' On the other hand, if the target sample is  detected to be far from all the source prototypes, it is then ex-  cluded from the cross-domain feature alignment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A (K+1)-way  classifier is learned in the second stage that additionally classi-  fies the detected target-private instances into the (K +1)th class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  An overview of our method is provided in the Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 2, and we  describe it in detail below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' COLOSEO: Contrastive Learning for OUVDA  To address the OUVDA, we employ contrastive learn-  ing (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' He et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) in both the stages to  (i) produce discriminative feature representations for both the  source and target data;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and (ii) align the source and target do-  mains over the shared classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We realize the above goals by  using four different versions of the contrastive losses that dif-  fer in a way the positives and negatives are created, which  are: (i) the label-based Sup-Con (Khosla et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) Lsup,  where positives consist of samples with the same class label  and negatives are the samples with a different class label;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (ii)  the augmentation-based contrastive loss Laug where the posi-  tives are the augmented views of a given sample, and negatives  consist of all other samples in the mini-batch;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (iii) the tempo-  ral contrastive loss Ltemp where the positives are the same as  in the augmentation-based Laug loss, but the negatives are cre-  ated by shuffling the order of the clips of the same video;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and  (iv) the cross-domain contrastive loss Lcross which is similar to  the Lsup, except that the pseudo-labels are utilized for the unla-  belled target samples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Given a mini-batch of source domain video sequences BS =  {(XS  i , yS  i )}b  i=1 and target domain video sequences BT = {XT  i }b  i=1  of size b, we apply two stochastic data augmentation transfor-  mations t(·) and ˜t(·) on each sample to create the positive pairs  (or views) as (XS  i , ˜XS  i ) and (XT  i , ˜XT  i ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As each video sequence  X consists of c clips, we first forward the clips through the fea-  ture extractor Φ(·) to obtain c clip-level features, which are then  fused using the clip aggregator network κ(·).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In detail, for ev-  ery input video sequence Xi the aggregator network κ(·) yields  a video-level feature hi = κ(Φ(Xi)) ∈ R1024.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Thus, correspond-  ing to the positive pairs (XS  i , ˜XS  i ) and (XT  i , ˜XT  i ) in the input  space we have (hS  i , ˜hS) and (hT, ˜hT) in the video-level feature  space R1024.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Following, the previous works on self-supervised  learning (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Khosla et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020), we also use a  non-linear projection head g(·) that operates on the video-level  features producing z = g(h).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Label-based Contrastive Loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Since the source data is an-  notated, we exploit the class label information to create more  informative positives and negatives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In detail, given an in-  stance XS  i belonging to the class yS  i , another instance XS  j is a  positive in the mini-batch if it shares the same class label, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  yS  i = yS  j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Similarly, all other instances in the mini-batch which  do not share the same class label with XS  i are considered neg-  atives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The label-based contrastive loss is then defined, for the  ith source sample, as:  Lsup  i  = − log  2b  �  j=1  1yS  i =yS  j exp(  sim(¯zS  i ,¯zS  j)  τ  )  exp(  sim(¯zS  i ,¯zS  j)  τ  )+  2b  �  k=1  1k�i1yS  k�yS  i exp(  sim(¯zS  i , ¯zS  k)  τ  )  ,  (1)  where ¯zS = zS ∪ ˜zS, sim(u, v) =  u⊺v  ∥u∥∥v∥ is the dot product  between the L2 normalized u and v and τ is a temperature pa-  rameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The operator 1k�i evaluates to 1 with k � i or 0 other-  5  wise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Similarly, the operator 1yS  k�yS  i yields 1 if the class labels  are different, or 0 otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Augmentation-based Contrastive Loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' For the unlabelled  target data, we use the augmentation-based contrastive loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Given an instance i, its positive is defined as the augmented  view of itself and its negatives are all the other instances in the  mini-batch.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We can define the augmentation-based contrastive  loss on the ith target sample as:  Laug  i  = − log  exp(  sim(zT  i ,˜zT  i )  τ  )  �2b  k=1 1k�i exp(  sim(zT  i ,zT  k)  τ  )  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  (2)  We make the Laug loss symmetric by swapping zT and ˜zT and  averaging the losses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Temporal Contrastive Loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' While the self-supervised con-  trastive loss is very much potent at modelling the shapes of ob-  jects in the clips while ignoring the low-level appearance in-  formation, it still might not be sufficient in the case of action  recognition due to the temporal dynamics associated with an  action.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Consider an example, where the network must discrim-  inate between the actions “push-up” and “pull-up”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Since  both these classes depict humans performing work-out routines,  the invariances induced by the strong augmentations in the con-  trastive loss would favour discovering the human shape, which  is confounding for the two action classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' However, the classes  “push-up” and “pull-up” inherently exhibit different tem-  poral dynamics, which are unique of their own.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We conjecture  that, asides from modelling the shape with the contrastive loss,  capturing the temporal dynamics can lead to even more dis-  criminative features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Thus, in order to benefit from the tempo-  ral information inherently conveyed in video data, we design a  video-oriented temporal contrastive loss that contrasts between  video sequences with shuffled and non-shuffled clips.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  As before, given a sample Xi, we create its positive view  ˜Xi with the help of a strong augmentation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Whereas, for con-  trasting with a regular video sequence, we artificially generate  negatives by randomly permuting the order of clips in Xi, pro-  ducing X−  i .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' However, as the contrastive loss requires a signifi-  cant amount of negatives in a mini-batch to work (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' He et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020), one would need perform repeated for-  ward passes through the clip aggregator network for every per-  mutation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To circumvent this, we simplified the contrastive for-  mulation to a triplet loss (Chechik et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2010), which achieves  a similar effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Then, the goal is to push the anchor Xi close  to the augmented sequence ˜Xi, while pushing Xi away from the  shuffled X−  i (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3) in the feature space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The temporal con-  trastive loss for the ith sample is given as:  Ltemp  i  = max{d(hi, ˜hi) − d(hi, h−  i ) + α, 0}  (3)  where d(·, ·) is a distance function defined as d(·, ·) = || · − · ||2,  where α indicates the margin of the triplet loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Cross-domain Contrastive Loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' While the aforementioned  contrastive losses can lead to a well-clustered feature space,  they do not guarantee that the source and target class clusters  are perfectly aligned.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' This is primarily caused by domain shift.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  PUSH  1  2  3  1  2  3  3  1  2  1  2  3  PULL  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3: An overview of the temporal contrastive loss Ltemp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The anchor and pos-  itive are created with transformations t(·) and ˜t(·), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The negatives  are artificially generated by shuffling the clips.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The Ltemp learns the temporal  dynamics by pulling the anchor towards the positive, and pushing the negative  far from the anchor  To further align the two domains, we propose to use a cross-  domain contrastive loss that is similar to the label-based con-  trastive loss Lsup, except that pseudo-labels are used for the un-  labelled target samples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In particular, to align a target sample  XT  i with the source samples, we first infer the pseudo-label ˆyT  i  of the ith target sample using the source classifier C(·).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Then we  proceed as in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (1) to define the cross-domain contrastive loss  as:  Lcross  i  = − log  2b  �  j=1  1ˆyT  i =yS  j exp(  sim(zT  i ,zS  j)  τ  )  exp(  sim(zT  i ,zS  j)  τ  )+  2b  �  k=1  1k�i1yS  k�ˆyT  i exp(  sim(zT  i , zS  k)  τ  )  ,  (4)  While inferring the pseudo-label of a target sample with  the K-way source classifier C(·) may work seamlessly in the  closed-set UVDA, it is problematic in the OUVDA case be-  cause of the presence of the target-private classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  To pre-  vent the target-private classes from being assigned to one of  the shared categories, we present an unknown class detection  protocol that eliminates the target samples that are unlikely to  belong to one of the shared classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Next we elaborate the un-  known class detection protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Recognizing the Open-set Actions  Before the pseudo-labels are inferred for the target samples,  we need a mechanism that can automatically detect the target-  private classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' For this purpose, we design a metric which  6  assigns a score to each target sample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' A low score means that  the target sample’s representation is far from the training data,  and is likely to be a target-private instance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' For this purpose, we  use cosine similarity as the metric between the target feature hT  i  and the nearest source class prototype.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The class prototype µk  for a source class k is obtained by averaging the features of all  the training samples of class k, which is defined as:  µk = 1  NS  k  NS  k  �  i=1  κ(Φ(XS  i ))  (5)  where NS  k is the number of source samples from the class k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  If the target feature hT  i is farther than its nearest source class  prototype µk by a threshold γ, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', it has cosine similarity lower  than the γ, we consider this sample as target-private.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Thus, we  have an indicator variable s which is 1 if a target sample XT  i is  target-private and 0 otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We can define it formally as:  si = 1  �  maxk∈{1,2,.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',K}(sim(hT  i , µk)) ≤ γ  �  (6)  where all the target samples with s = 1 are not included in the  cross-domain contrastive loss Lcross.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Since the final goal in the OUVDA is not only to classify  the shared target instances into one of the K classes but also to  classify all the target-private instances into the (K + 1)th class,  we initialize a (K + 1)-way classifier C′(·) in the second stage  of training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' All the target samples where s = 1 using Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (6)  are assigned an “unknown” label K + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We then use a standard  cross-entropy loss to assign a high likelihood to the target pri-  vate instances to be belonging to the (K + 1)th class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Whereas,  for the source samples we keep the standard classification loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  The cross-entropy loss is for a source XS  i and target-private in-  stance XT  i,s=1 is defined as:  Lopen  i  = −  1  K + 1  K+1  �  j=1  yi,j log ψ(C′(κ(Φ(Xi))))  (7)  where ψ(·) is the softmax function for normalizing the network  logits into a probability distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Note that in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (7), for  a target-private instance XT  i,s=1, we backpropagate only for the  (K + 1)th class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Overall objective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We train our model with a mini-batch using  the following final objective:  L = Lopen + Lsup + Laug + Lcross + λLtemp  (8)  where λ is a weight for the temporal contrastive loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Inference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' During inference the classifier C′(·) is used for clas-  sifying the target samples into one of the known or the unknown  (K + 1)th category.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Experiments  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Experimental Set-up  Benchmarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We evaluate our proposed framework under  the OUVDA task on four benchmarks that are derived from  UCF101 (Soomro et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2012), HMDB (Kuehne et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  2011), Olympic Sports (Niebles et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2010) and Epic  Kitchens (Damen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2018) action recognition datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The  four benchmarks are described below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  The HMDB↔UCF (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021) benchmark is con-  structed by collecting the 12 overlapping categories, viz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  Climb, Fencing, Golf, Kick Ball, Pull-up, Punch,  Push-up,  Ride Bike,  Ride Horse,  Shoot Ball,  Shoot Bow and Walk, present in the HMDB and UCF-101  datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Out of these 12 classes, the first six of them are se-  lected as shared classes and the remaining six as target-private  classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Similarly, the UCF↔Olympic benchmark contains  six overlapping categories, viz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', Basketball, Clean and  Jerk, Diving, Pole Vault, Tennis and Discus  Throw, from the UCF-101 and the Olympic Sports datasets,  where the first half are shared classes and the rest are target-  private ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' For both of these two benchmarks we follow the  splits proposed in the CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Given saturated performance on the above benchmarks, we  also consider the benchmarks which is constructed from the  egocentric action recognition dataset Epic Kitchens (EK).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The  original EK dataset is composed of first-person video sequences  depicting egocentric actions (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='“insert”, “mix”, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=') per-  formed in various kitchen environments, with a total of 32 en-  vironments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The closed-set UVDA work MM-SADA Munro  and Damen (2020) introduced a UVDA benchmark with three  kitchens P01, P22 and P08 from the EK as the three domains  D1, D2 and D3, respectively, with eight action classes (viz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  Put, Take, Open, Close, Wash, Cut, Mix, Pour) over-  lapping among them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We adapt these three domains as a bench-  mark for the OUVDA by additionally including all the instances  from the non-overlapping classes of the target domain as target-  private.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Evaluation metrics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To compare our proposed COLOSEO to  the baselines we adopt the metrics reported in the recent OU-  VDA work CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Specifically, we report:  the ALL (or the K+1 way) accuracy that is the percentage of  correctly predicted target samples over all the target samples;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  the OS∗ is the averaged class accuracy over the known classes  only;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' the UNK recall metric which denotes the ratio of correctly  predicted “unknown” target instances over the total number of  “unknown” instances;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and the HOS =  OS∗×UNK  OS∗+UNK which is the  harmonic mean between the known OS∗ and unknown UNK  accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The HOS is the preferred metric in the open-set liter-  ature (Bucci et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Saito and Saenko, 2021) because the  model can classify all the target instances to “unknown” class  and attain 100% UNK accuracy but 0% OS∗ accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Thus,  in order to have a high HOS score the model must do well in  both the OS∗ and the UNK metrics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Note that the CEVT also  reports OS, the open-set average accuracy over the classes, but  is similar to the ALL accuracy in nature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Being redundant, we  do not report the OS accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Implementation details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We use the I3D architecture as back-  bone, pretrained on Kinetics-400 as provided by Carreira and  Zisserman (2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We input c = 3 clip-level features, each  of dimension 1024 to the aggregation module κ, which out-  puts a 1024 dimensional feature h.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Both the projection head  7  Method  Backbone  HMDB→UCF  UCF→HMDB  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  DANN (Ganin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='4  Table 1: Comparison with the state-of-the-art performance on the HMDB↔UCF benchmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content=' Overall, our proposed COLOSEO outperforms the  state-of-the-art methods in terms of the important HOS metric  Method  Backbone  UCF→Olympic  Olympic→UCF  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  DANN (Ganin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content=', 2014)  ResNet101  94.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='9  COLOSEO-E (ours)  92.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='0  COLOSEO (ours)  98.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  100.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content=' Overall, our proposed COLOSEO outperforms several state-of-the-art  methods in terms of the HOS score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Best and second best numbers are highlighted in bold and underlines, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The numbers of methods using ResNet101  as backbone are taken from Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Note that this benchmark is smaller with only three shared and three unknown categories, and thus results have  mostly saturated  g(·) and κ(·) modules are implemented as a 2-layer MLP net-  work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The classifiers C and C′ are implemented as linear lay-  ers, with input 1024 (video-level feature) and output equal to  K and K + 1, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In both the stages we trained our  network with an SGD optimizer having momentum as 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9, and  learning rates 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='01 for the HMDB↔UCF and UCF↔Olympic,  whereas 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='001 for the Epic-Kitchens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We use batch size equal  to 16 for all settings, and the parameter α was kept at the de-  fault value of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Our code is publicly available at https:  //github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='com/gzaraunitn/COLOSEO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Baselines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We adopt the baselines from Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (2021),  most of which are closed-set UDA methods adapted to the  open-set scenario using OSVM (Jain et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2014).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In de-  tails, we report DANN (Ganin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2015), JAN (Long  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2016), AdaBN (Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2018), MCD (Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=',  2018a), OSBP (Saito et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2018b) and video-oriented TA2N,  TA3N (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2019) and CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Moreover, we compare with an image-based OUDA method  OVANet (Saito and Saenko, 2021), which we re-purposed  to make it video-oriented.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  We additionally compare to the  CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021) that uses the I3D backbone (Car-  reira and Zisserman, 2017), instead of the original Resnet-101,  for a fair comparison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Finally,  we also consider a variant of our proposed  COLOSEO, where the target-private rejection is carried out  by thresholding the entropy computed by the closed-set classi-  fier C(·), instead of using the source prototypes as described in  Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We call this variant as the COLOSEO-E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Through our  experiments we demonstrate that this entropy-based variant is  often suboptimal with respect to our final method COLOSEO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Comparison to the State of the Art  We report in the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 1, 2 and 3 the results obtained on  the HMDB↔UCF, UCF↔Olympic and Epic-Kitchens bench-  marks, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Overall, we observe from these tables that  our proposed COLOSEO outperforms the competitors in 8/10  adaptation settings in terms of the all important HOS metric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In details, from the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  1 we can see that for the  UCF→HMDB adaptation setting our proposed COLOSEO  yields the best UNK and HOS metrics, and the second best  closed-set accuracy denoted by OS∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In addition, COLOSEO  achieves the best score for the ALL metric as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' On the  other hand, for the reverse adaptation setting HMDB→UCF,  although our COLOSEO does not outperform the competitors  in individual metrics, it surpasses them in terms of the HOS, by  obtaining a better balance between OS∗ and UNK.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' On the con-  trary, we can observe that several competitors fail to maintain a  good trade-off between the OS∗ and UNK, achieving a higher  8  Method ↓  Setting →  D2→D1  D3→D1  D1→D2  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021)  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='3  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  93.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='4  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  OVANet (Saito and Saenko, 2021)  29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  COLOSEO-E (ours)  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  88.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  COLOSEO (ours)  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='5  Method ↓  Setting →  D3→D2  D1→D3  D2→D3  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021)  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='2  OVANet (Saito and Saenko, 2021)  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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+page_content='0  COLOSEO-E (ours)  28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  COLOSEO (ours)  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  47.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  Table 3: Comparison to the state-of-the-art performance on the Epic-Kitchens benchmark (with domains as D1, D2 and D3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' All the methods use I3D as backbone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Best and second best numbers are highlighted in bold and underlines, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Overall, our proposed COLOSEO-E and COLOSEO outperform the existing  state-of-the-art methods in terms of the HOS score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  value in one or the other metric, but at the cost of a severe drop  in the other one, resulting in a lower overall HOS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  As for UCF↔Olympic benchmark, it is worth noting that  the benchmark is very small (composed of only three known  and three unknown classes) and has saturated performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Nonetheless, we can observe in the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 2 that COLOSEO  has competitive or better HOS scores when compared to  its competitors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In particular, in the Olympic→UCF setting  COLOSEO achieves the best HOS score, whereas in the re-  verse direction our other variant COLOSEO-E outperforms ev-  ery method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3 we report the results for the challenging Epic-  Kitchens (EK) benchmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' For the EK benchmark we com-  pare our proposed method with two existing state-of-the-art  image-based OVANet and video-based CEVT methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' From  a first glance we notice that the overall scores in the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3 is  lower as compared to the HMDB↔UCF and UCF↔Olympic  benchmarks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  This can be attributed to: the challenging na-  ture of the first-person (egocentric) actions performed in clut-  tered indoor kitchen environments;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and the mismatch of the  I3D pre-training Kinetics dataset containing actions from third-  person views performed outdoor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Nevertheless, our two vari-  ants COLOSEO-E and COLOSEO outperforms the existing  state-of-the-art in several adaptation settings of the EK.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In particular, the results in the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3 show that COLOSEO’s  HOS score generally benefits from a higher closed-set accu-  racy OS∗ when compared to other methods, although it doesn’t  achieve the best score with respect to the open-set accuracy  UNK.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Contrary to our proposed method, the competitor method  CEVT is prone to classifying most of the target instances as  “unknown”, as evident from high UNK accuracy but very low  closed-set accuracy OS∗.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  This leads to the CEVT exhibit-  ing significantly lower HOS scores when compared to our  COLOSEO-E and COLOSEO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Ablation Analysis  We report the results of a thorough ablation analysis of  the COLOSEO framework conducted to better understand  the impact of the proposed components and the sensitivity of  COLOSEO to the hyperparameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Method  ALL  OS∗  UNK  HOS  Ours w/o Lsup  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  71.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  89.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  Ours w/o Laug  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  Ours w/o Lcross  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  90.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  Ours w/o Ltemp  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  Ours w/o Lsup, Laug, Lcross  71.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  81.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  Ours (full)  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  81.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  88.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  Table 4: Ablation study of the contrastive losses in our COLOSEO in the  HMDB→UCF adaptation setting  Impact of the contrastive losses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' First, we analyze the impact  of the contrastive losses on the performance obtained by the  proposed COLOSEO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 4 we report the performance  of COLOSEO for the adaptation setting HMDB→UCF when  removing the individual contrastive losses described in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  In details, we ablate by removing Lsup, Ltemp, Lcross and Laug  one at a time from the final objective in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We can ob-  serve that all the contrastive losses positively contribute to the  final score and removing any of them negatively impacts the  metrics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Notably, the absence of the newly proposed temporal  contrastive loss Ltemp leads to a significant drop in performance  (by -6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3% points).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' This highlights the importance of leveraging  the temporal information in videos for a well structured repre-  sentation space, which can be realized for free without needing  any labels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Furthermore, note that even without the cross-domain align-  ment loss Lcross the performance is relatively high, with a drop  of only 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8% points, which is lower than without the Ltemp loss  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3% points drop).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' It hints at the fact that the Ltemp and Laug  can effectively and implicitly align the two domains without  needing any alignment technique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Method  # clips = 3  # clips = 4  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  COP  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  90.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  COLOSEO  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  81.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  88.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  Table 5: Comparison of the COLOSEO to the COP baseline and the impact of  the number of clips c in the HMDB→UCF adaptation setting  9  Method  HMDB→UCF  UCF→HMDB  ALL  OS∗  UNK  HOS  ALL  OS∗  UNK  HOS  CEVT (Chen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2021)  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9±9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2±6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8±8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6±5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7±11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  89.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2±5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1±7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  COLOSEO-E (ours)  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1±3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3±7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8±2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0±2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  81.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4±6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  94.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8±7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='3  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9±3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1  COLOSEO (ours)  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='7±3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='8  90.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9±2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='4±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5±3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9±4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='2  93.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0±4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='6  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9±2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9  Table 6: Comparison of the averaged performance under three different splits of the shared and unknown classes on the HMDB↔UCF benchmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Each entry  reports the average and the standard deviation of a metric across three splits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' All the methods use I3D as backbone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Best average performance is highlighted in bold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Overall, the COLOSEO consistently and substantially outperforms the CEVT, while having lower variance than CEVT in both the adaptation settings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='35  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='40  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='45  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='50  0  20  40  60  80  100  HOS (in %)  COLOSEO  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 4: Impact on the HOS score while varying the threshold value γ, which  is used for the known/unknown target separation in the COLOSEO, in the  HMDB→UCF adaptation setting  Comparison to video-based pretext task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Temporal informa-  tion offered by video data has previously been exploited in a  UVDA method SAVA (Choi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2020) that in particular uses  the clip ordering prediction (COP) as a pretext task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In details,  the COP consist in training the model to predict the correct or-  der in which the input clips have been permuted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The key idea is  that while trying to distinguish between the input clips that are  temporally shuffled from the non-shuffled (or original) ones,  the network will learn salient and representative features from  the actions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Given that our proposed temporal loss Ltemp shares  similar spirit with the pretext task of COP, we also compare and  report in Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 5 the results obtained with COLOSEO, except by  replacing Ltemp with the COP loss, for c = 3 and c = 4 clips.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  It is evident from the Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 5 that our Ltemp significantly outper-  forms the COP baseline, which produces much more unstable  results, with a tendency to either over-accept or over-reject sam-  ples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Furthermore, when using 4 clips, the COP loss produces  a drastic drop with respect to the final score, as the ordering  problem becomes more challenging (being a c!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='-way classifi-  cation problem), which aligns with the findings in Choi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  (2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In contrast to the COP loss, our temporal loss is signif-  icantly more robust to the increased number of clips, which is  evident by an increased gap in the HOS scores between the two  methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Sensitivity to hyperparameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In the Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 4 we demonstrate  the sensitivity analysis on the hyperparameter γ described in the  Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The γ governs whether to assign a target instance to a  shared class or reject it as target-private class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' The Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 4 shows  that HOS score of our COLOSEO remains fairly stable over a  wide range of γ values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' From our experiments we observe that  10  1  10  0  10  1  0  20  40  60  80  100  HOS (in %)  COLOSEO  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 5: Impact on the HOS score while varying λ, which weights the temporal  contrastive loss, in the HMDB→UCF adaptation setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Note that the x-axis is  in logarithmic scale  extreme low or high values of γ results in the protocol over-  accepting and over-rejecting target instances, respectively, thus  favoring one of the metrics between OS∗ and UNK but impact-  ing negatively the final HOS score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Thus, we limit the values  of γ within reasonable limits despite the theoretical bounds of  γ lies in [0, 1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  We also ablate on the second hyperparameter λ that con-  trols the contribution of the temporal contrastive loss Ltemp to  the final objective described in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Given our implementa-  tion of the Ltemp, described in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 3, uses a triplet loss instead  of the traditional InfoNCE contrastive objective (Gutmann and  Hyv¨arinen, 2010), we had to balance the maginitude of the  Ltemp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In the Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 5 we plot the HOS score by varying the λ  in logarithmic scale.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We can observe that the chosen value in  the final version of our framework (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' λ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='1) leads to the  best HOS score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Furthermore, it emerges that the HOS score  remains quite stable until λ = 1, and only degrades for very  large values (λ = 10), which is a reasonable behaviour.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Impact of shared/unknown classes splits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As shown in the  open-set recognition literature (Vaze et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=', 2022), the UNK  performance relies heavily on the split between the shared and  OOD classes, it also becomes imperative to test the OUVDA  methods under different shared/unknown classes splits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' To this  end, we report in Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 6 the averaged results obtained by our  proposed method and compare them to the best competitor  CEVT under three random splits of 6 shared and 6 unknown  classes of the HMDB↔UCF benchmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  We can see that  our COLOSEO and COLOSEO-E outperforms the CEVT  by significant margins even under different different splits of  the shared and unknown classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' More interestingly, the stan-  10  dard deviation in the HOS score attained by our COLOSEO is  also substantially lower than that of CEVT (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='5 versus 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='0 and  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9 versus 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='9 in the HMDB→UCF and UCF→HMDB adapta-  tion settings, respectively).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' This shows that irrespective of the  shared action categories present in the source, the representa-  tion space learned by COLOSEO is more compact and thereby  rejecting unknown classes becomes easier than the weighted  adversarial strategy used in the CEVT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  0  10  20  30  40  50  Epoch  56  58  60  62  64  66  68  ALL (in %)  COLOSEO  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 6: The evolution of the pseudo-label ALL accuracy of COLOSEO on the  target domain with the progression of training in the HMDB→UCF adaptation  setting  Quality of pseudo-labels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Given our cross-domain contrastive  loss Lcross in the Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 4 relies on the pseudo-labels computed  on the target, in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' 6 we visualize the ALL accuracy metric  of the pseudo-labels for the HMDB→UCF adaptation setting,  as the training progresses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' As expected, we observe that ALL  pseudo-label accuracy on the target training data is increasing  as the training progresses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' This in turn positively impacts the  Lcross to better align the source and the shared target classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Moreover, as the ALL also includes the accuracy of the un-  known class prediction, it also indirectly reflects the usefulness  of the unknown target rejection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' Conclusions  In this work we presented the COLOSEO framework for  addressing open-set unsupervised video domain adaptation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content='  Our proposed COLOSEO leverages contrastive learning under  complementary yet unified formulations to: (i) learn discrim-  inative and compact feature representations in both the source  and target domains;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' and (ii) align source and target distributions  with respect to the shared classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' In particular, the COLOSEO  includes a video oriented temporal contrastive loss that clusters  different actions by exploiting the temporal information avail-  able freely in video data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We showed that learning compact  representations can simplify the separation between the shared  and unknown classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
+page_content=' We carried out an extensive experimental  evaluation on three OUVDA benchmarks and demonstrated that  our COLOSEO significantly outperforms the existing state-of-  the-art methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_dE1T4oBgHgl3EQfogTY/content/2301.03322v1.pdf'}
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diff --git a/_tE5T4oBgHgl3EQfSQ5r/content/tmp_files/2301.05527v1.pdf.txt b/_tE5T4oBgHgl3EQfSQ5r/content/tmp_files/2301.05527v1.pdf.txt
new file mode 100644
index 0000000000000000000000000000000000000000..6539b948a8e26b04af95a3c8abd6fa6c1dcf2758
--- /dev/null
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@@ -0,0 +1,1226 @@
+Reconstruction of three-dimensional strain field in an asymmetrical 
+curved core-shell hetero-nanowire 
+ 
+Serhii Kryvyi1,*, Slawomir Kret1 and Piotr Wojnar1 
+1Institute of Physics Polish Academy of Sciences, al. Lotnikow 32/46, 02-668 Warsaw, 
+Poland 
+ 
+E-mail: kryvyi@ifpan.edu.pl 
+ 
+Abstract 
+Crystal orientation and strain mapping of an individual curved and asymmetrical 
+core-shell hetero-nanowire is performed based on transmission electron microscopy. It 
+relies on a comprehensive analysis of scanning nanobeam electron diffraction data 
+obtained for 1.3 nm electron probe size. The proposed approach handles also the problem 
+of appearing twinning defects on diffraction patterns and allows for investigation of 
+materials with high defect densities. On the basis of the experimental maps and their 
+comparison to finite element simulations, a hidden core-shell geometry and full three-
+dimensional strain distribution within the curved core-shell nanowire are obtained. As 
+effect, a low-dose quasi-tomography data using only single zone axis diffraction 
+experiment is received. Our approach is applicable also for electron beam sensitive 
+materials for which performing conventional tomography is a difficult task. 
+ 
+Keywords: strain mapping, orientation mapping, nanobeam electron diffraction, 3D 
+strain reconstruction, quasi-tomography, nanowire. 
+ 
+Headlines: 
+Unique approach for strain and orientation mapping within a single nano-object with 
+defects 
+Strain and orientation mapping of single curved highly-asymmetric core-shell 
+nanowire 
+A detailed description of the method for 3D strain reconstruction in core-shell 
+nanowire based on single zone axis diffraction pattern and its comparison to finite element 
+method simulation 
+ 
+ 
+
+1. Introduction  
+Epitaxial hetero-nanowires (NWs) represent a novel technological platform with a 
+wide range of applications in nanotechnology, covering a number of electronic and 
+photonic devices, as well as sensors [1]. Among others, the core-shell NWs have attracted 
+a great deal of attention for their applications in future nanodevices. Implementation of 
+core-shell geometry allows for the enhancement of the light extraction efficiency from light-
+emitting diodes (LEDs), a significant increase of light absorption in solar cells, and an 
+effective electric field control of electric current in transistors resulting in a considerable 
+improvement of the device performance [2]–[4]. The presence of the shell may additionally 
+result in the enhancement of optical emission intensity from the NW-cores, as 
+demonstrated for GaAs/(Ga,In)P [5] and (Zn,Mn)Te/(Zn,Mg)Te core/shell nanowires [6]. 
+Moreover, 
+the 
+core-shell 
+NWs 
+are 
+promising 
+building 
+block 
+for 
+nanoelectromechanical systems (NEMS) [7],[8]. However, due to the lattice mismatch 
+between the core and the shell semiconductor, the core-shell configuration introduces a 
+relatively complex anisotropic three-dimensional (3D) lattice distortion in contrast to two-
+dimensional (2D) tetragonal distortion typical for thin epilayers deposited on a thick lattice-
+mismatched substrate. This principally different behavior originates from the relatively 
+small lateral dimensions of the NWs and the large surface-to-volume ratio typical for these 
+structures.  
+For axial NW heterostructures, it is well known that the critical thickness increases 
+with decreasing NW’s radius [9]. In the case of radial NW heterostructures the situation is 
+more complex. In particular, the contribution of surface and interface energy significantly 
+affects the strain relaxation mechanism in core-shell NW heterostructures. Therefore, it is 
+more appropriate to use the concept of critical dimensions instead of only one critical 
+thickness. The NW critical dimensions: NW length, core radius, and shell thickness, 
+depend on each other [10]. Moreover, they are also affected by NW crystallographic 
+orientation and the presence of facets. 
+Significant strain fields that occur in lattice mismatched core-shell NWs can cause 
+the formation of lattice defects, misfit dislocation in most cases, and surface morphological 
+transformations, such as stress-driven surface roughening [11]–[13]. In addition, the 
+influence of the core cross-section shape on the strain field in core-shell NWs has been 
+reported [14]. Importantly, core-shell NWs are very sensitive to radial inhomogeneity. Even 
+small asymmetry of the shell composition or NW-core decentering leads to the occurrence 
+of noticeable asymmetric strain fields and, as result, bending of the NW. This bending 
+reduces stresses in the NW heterostructure and, thus, leads to the avoidance of defect 
+formation. 
+
+Strain fields that inevitably occur in lattice mismatched core-shell NWs have a 
+significant impact on their optoelectronic properties and, in spite of the potential formation 
+of defects, can be used to fine-tune effectively the band gap energy [15]–[18]. Moreover, 
+the radial core-shell geometry of the NW heterostructures gives rise to the realization of a 
+number of crystalline coherent structures unobtainable in classic planar configuration 
+[19],[20]. These findings motivate the investigation of strain fields in core-shell hetero-
+NWs. Understanding and prediction of the strain relaxation mechanism is crucial for the 
+development of novel and the improvement of the quality of existing hetero-NW based 
+devices. Therefore, a significant number of papers is dedicated to the study of strain 
+distribution within core-shell NWs has appeared [13],[21]–[36].  
+Among different experimental techniques, only X-ray synchrotron and transmission 
+electron microscopy (TEM) based methods provide an opportunity for strain mapping with 
+a sufficiently high spatial resolution. Our previous report has shown that using scanning 
+nanobeam electron diffraction (NBED) in TEM allows us to overcome the difficulties 
+related to NW thickness variations and twinning of a crystal structure [37] and leads to the 
+realization of precise 2D strain maps of axial NW heterostructures. Our approach does not 
+employ the precession of electron beam, but it makes possible the conservation of 
+dynamical effects on diffraction pattern (DP) during acquisition of experimental data. The 
+dynamical features in diffraction disks, for instance, can be effectively used for specimen 
+thickness determination with nanometer precision [38],[39]. 
+The purpose of this study is to use the intensity distribution of reflections together 
+with their position for the realization of crystal orientation maps in addition to strain maps. 
+To achieve this goal, the so-called template matching technique is applied. It relies on the 
+comparison of each experimental diffraction pattern to the database of pre-simulated 
+dynamical DPs for different misorientation angles. As an effect, the crystalline orientation 
+mapping is performed with unusually high resolution. Those results allow us to reveal 
+quasi-tomography data of a core-shell NW and to conduct a full reconstruction of the strain 
+field within an individual complex nano-object. 
+A similar approach described previously used the commercial ASTAR software (by 
+Nanomegas) to recognize the phase and crystal orientation in polycrystalline materials 
+[40]. In that case the kinematical electron diffraction approximation has been employed to 
+generate the template database. A recent paper reported using a dynamic approach for 
+orientation mapping [41]. However, those approaches rely on the precession of electron 
+beam for collecting of experimental data. Those limitations impair the angular resolution for 
+the crystal orientation mapping. While a typical angular resolution of 1 degree is well 
+
+enough for a polycrystalline sample it is not sufficient for a monocrystalline object which is 
+subject of our present study. 
+For the investigation of a single monocrystalline NW the use of X-ray micro Laue 
+diffraction [42] and selected area electron diffraction (SAED) [43] for local lattice 
+orientation and strain profiling along the NW axis have been reported. Both approaches 
+are characterized by an order of magnitude better angular resolution for local lattice 
+orientation as compared to the previously mentioned kinematical approach [40], but the 
+spatial resolution remains poor. Therefore, a new approach is required to map small 
+angles of misorientation for single-crystal objects.  
+In this work, we study the strain distribution in radial (core-shell) NW 
+heterostructures by a conventional TEM technique. NBED is used for the relative lattice 
+mapping with picometer precision and a few nanometers spatial resolution. In addition to 
+the lattice mapping, the pattern matching technique provides additional information about 
+the sample such as its thickness and local crystallographic orientation. The proposed 
+approach allows us, therefore, to obtain local crystallographic orientation mapping with 
+ultimate precision up to 0.1 degree. The obtained data are used to create realistic finite 
+element method (FEM) models to perform full three dimensional tomography 
+reconstruction of strain field in radial NW heterostructure. 
+ 
+2. Methods 
+The ZnTe/(Cd,Zn)Te core-shell NWs were grown on (111)-oriented Si substrate by 
+molecular beam epitaxy (EPI 620 system) with the use of Au nano-catalysts employing the 
+vapor–liquid–solid (VLS) growth mechanism. 1-nm-thick gold layer was pre-deposited on 
+the Si substrate and heated up to 450°C to induce the formation of Au-Si liquid nano-
+droplets which serve as catalysts for the further ZnTe NWs growth. (Cd,Zn)Te shells are 
+deposited after the reduction of the substrate temperature to 350°C, at which the catalyst 
+droplets are frozen leading to the epitaxial overgrowth of ZnTe NWs. The detailed growth 
+procedure is almost the same as described in Ref. [44]. 
+Structural investigations and elemental composition characterization were 
+performed using an objective lens corrected FEI Titan Cubed 80-300 microscope 
+operating at 300 kV. For the TEM examination, the NWs were transferred mechanically by 
+sliding a copper grid covered with holey carbon film across the sample surface with NWs. 
+High-resolution transmission microscopy (HR-TEM) images were acquired by Gatan 
+Ultrascan 1000 charge coupled device (CCD) camera. For high-resolution scanning 
+transmission electron microscopy (HR-STEM) in annular dark field mode, the high-angle 
+annular dark-field (HAADF) Fischione 3000 detector was used. Nanobeam electron 
+
+diffraction (NBED) mapping of (Cd,Zn)Te/ZnTe hetero-NW was performed in STEM mode 
+using the Gatan Ultrascan 1000 camera with binning 4 to increase the dynamic range and 
+to reduce a blooming effect. Diffraction patterns were acquired with a convergence semi-
+angle of 1 mrad and a probe size of 1.3 nm [37]. The integration time for NBED acquisition 
+was chosen to be 100 msec per frame. Energy dispersive X-ray spectroscopy (EDX) data 
+were collected in TEM by EDAX 30 mm2 Si(Li) detector with a collection angle of 0.13 
+srad. 
+The analysis of NBED data was performed by a scripting procedure using 
+DigitalMicrograph software. To obtain precise strain maps with subpixel accuracy the 
+circular Hough transform was implemented in the script [37],[45]. The pattern matching 
+technique to correlate experimental diffraction patterns and simulated data was used to 
+obtain local orientation maps of bent NW. Since NBED data was collected for [110] zone 
+axis, the orientation mapping in our case is based on the determination of crystallographic 
+misorientation of the NW with respect to [110] zone axis. The procedure is based on a 
+cross-correlation algorithm and is also implemented in the DigitalMicrograph script. The 
+simulation of tilt series was performed using QSTEM software which is based on a 
+dynamical approach and a multislice algorithm [46]. A set of misoriented DPs was 
+simulated for [110] ZnTe crystal misoriented in in the range from -4 to 4 degrees towards 
+[001] and [11̅0] crystallographic directions with step of 0.02 degrees. These tilt series were 
+simulated for crystal thicknesses up to 80 nm with the step of 1 nm. 
+The finite element method (FEM) modeling of (Cd,Zn)Te/ZnTe core-shell NW was 
+performed by COMSOL Multiphysics software. The 3D model was developed based on the 
+measured geometric characteristics of NW. The model consists of ZnTe NW-core 
+surrounded by an asymmetric (Cd,Zn)Te shell. Crystallographic orientation and anisotropy 
+of Young modulus [37] were also taken into account in the model. The simulated NW has 
+the shape of a hexagonal frustum with the height of 235 nm and the length of the bottom 
+face edge of 30 nm and that of the top face of 25 nm. The last two numbers can be 
+roughly considered as radii of the NW on the bottom and top bases, respectively. To 
+eliminate surface relaxation effects on the bottom and top NW bases additional segments 
+with 50 nm height were added to these bases. These additional parts were not considered 
+in the analysis of the simulated data. 
+ 
+3. Structural studies 
+EDX elemental mapping of a typical ZnTe/(Cd,Zn)Te NW segment confirms the 
+radial character of the NW heterostructure. However, an asymmetry in the shell thickness 
+occurs, which is confirmed by the irregular radial distribution of cadmium across the 
+
+measured NW heterostructure (Fig. 1(b)). The average Cd content, x, in CdxZn1-xTe shell 
+determined by EDX is about 0.6±0.05. In the core-shell configuration the asymmetrical 
+shell and the relatively large lattice misfit between ZnTe core and (Cd,Zn)Te shell leads to 
+a significant bending of the NW (Fig. 1(a)). As a result, atomic columns within this NW 
+heterostructure are also bent having as a consequence that the standard geometrical 
+phase analysis (GPA) method is not applicable for monitoring lattice changes on a large 
+fragment of this sample. Nevertheless, the HR-TEM/STEM investigations evidenced an 
+epitaxial growth of the (Cd,Zn)Te shell on the ZnTe core. No misfit dislocations between 
+the core and the shell were observed, whereas the crystalline structure of the shell is 
+exactly the same as the crystalline structure of the NW core. Twin boundaries propagating 
+from the core to the shell without any discontinuity were observed (Fig. 1(b)). In addition, a 
+thin 4-5 nm amorphous layer on the NW surface is present. We associate it to the 
+oxidation of NWs in the air, which is confirmed by the increased oxygen content on the 
+surface found in EDX data. 
+ 
+Figure 1. (a) The High Angle Annular Dark Field image of ZnTe/(Cd,Zn)Te core-shell NW 
+measured in [110] zone axis; the rectangle represents an area investigated by nanobeam electron 
+diffraction (NBED). (b) HR-TEM image of a typical NW segment; dashed lines indicate the 
+hypothetical position of ZnTe core. The red and blue line profiles represent the intensities of CdL 
+and ZnK lines from EDX spectra averaged across the NW, respectively. The inset represents the 
+schematic image of an asymmetric core-shell NW cross-section. 
+ 
+4. Strain mapping 
+Diffraction patterns for (Cd,Zn)Te/ZnTe radial NW heterostructure were acquired as 
+a grid of scans recorded point by point, line by line, and finally as a 3D stack. The 
+
+(a)
+(q)
+[111]
+[110]
+[112]
+ZnTe
+Cd,Zn)Te shell
+ZnTe core
+(Cd,Zn)Te
+(Cd,Zn)Teshell
+Zn
+4.5nm
+Cd
+10nm
+[112]
+[110]
+50nmacquisition area with a sampling of 24 px in the radial and 60 px in the axial direction of the 
+NW was used. The pixel size was 2.82 nm and 3.91 nm for x and y directions, 
+respectively, leading to the total area with dimensions 67.6×235 nm. Diffraction patterns 
+were recorded for each electron beam position, thus, the final experimental stack consists 
+of 1440 diffraction patterns. 
+NBED was used to analyze the local crystal lattice deformation, i.e., to perform the 
+strain mapping of the core-shell NW heterostructure. For this reason, the scripting 
+procedure written in DigitalMicrograph software was used. This procedure consists of 
+finding the distance 𝒈ℎ𝑘𝑙 between (000) disk and a diffraction disk with (hkl) indexes. The 
+choice of disk that corresponds to diffraction from a certain crystal plane allows for 
+mapping of the interplanar spacing for specific crystallographic directions. Typically, the 
+relative strain is introduced into this procedure: 
+𝜀ℎ𝑘𝑙
+𝑟𝑒𝑙 =
+𝑑ℎ𝑘𝑙
+𝑒𝑥𝑝−𝑑ℎ𝑘𝑙
+𝑟𝑒𝑓
+𝑑ℎ𝑘𝑙
+𝑟𝑒𝑓
+  
+(1) 
+where 𝑑ℎ𝑘𝑙
+𝑒𝑥𝑝 and 𝑑ℎ𝑘𝑙
+𝑟𝑒𝑓 are an experimental and reference interplanar spacing value for (hkl) 
+lattice planes respectively. Or in terms of reciprocal space, using |𝒈ℎ𝑘𝑙|~
+1
+𝑑ℎ𝑘𝑙, Eq. (1) can 
+be written as: 
+𝜀ℎ𝑘𝑙
+𝑟𝑒𝑙 =
+|𝒈ℎ𝑘𝑙
+𝑟𝑒𝑓|−|𝒈ℎ𝑘𝑙
+𝑒𝑥𝑝|
+|𝒈ℎ𝑘𝑙
+𝑒𝑥𝑝|
+  (2) 
+where 𝒈ℎ𝑘𝑙
+𝑒𝑥𝑝 and 𝒈ℎ𝑘𝑙
+𝑟𝑒𝑓 are an experimental and reference distance between (000) and (hkl) 
+disk, respectively. As the reference, an experimentally obtained value is usually used. As a 
+result, a strain map represents lattice change with respect to a reference area on the map. 
+In our considerations, we have chosen an area with maximal g value (i.e. minimal value of 
+interplanar spacing) as the reference. However, in the case of core-shell NW, it also may 
+be useful to use other reference values. For example, the absolute strain 𝜀𝑎𝑏𝑠 can be 
+calculated using the relaxed value of core and shell lattice as a reference for the core and 
+shell region, respectively.  
+It should be noted, that information obtained by NBED is averaged along the 
+electron nanobeam path. That is why the strain maps represent projections of lattice 
+change on the image plane. Nevertheless, maps can also be a function of electron probe 
+defocus. In our case however, the latter effect can be neglected due to the large depth of 
+field typical 1 mrad convergent probe. This significantly simplifies strain appearance 
+represented on maps compared to complicated real 3D behaviors of the lattice plane in 
+asymmetric core-shell NW. 
+Prior to performing the strain mapping, one has to link the crystallographic 
+directions and the geometry of the NW (Fig. 2(a)). As can be seen in Fig. 2(a), the 
+
+identification of (22̅4̅) and (11̅1) reflections lead us to determine directly radial 𝜀𝑟
+𝑟𝑒𝑙 and 
+axial 𝜀𝑎
+𝑟𝑒𝑙 strain in NW, respectively. Please note, that in the case of our measurements we 
+have the insight into the strain component perpendicular to the electron beam only. That is 
+why the radial strain 𝜀𝑟
+𝑟𝑒𝑙 in our considerations is restricted to this component only.  
+Importantly, a large number of crystal twins typical for (Cd,Zn)Te structure makes it 
+difficult to analyze NBED data. According to analyzed NBED data, several types of DP can 
+be found on the experimental stack. The first one is a regular pattern, as shown in Fig. 
+2(a), there are no difficulties to analyze such DP. The second type represents a pattern in 
+which the diffraction from both twins appears simultaneously (Fig. 2(b)). In this case the 
+electron probe reaches a region that is close to the twin boundary. 
+The situation is more complex in the case of the other three types. Additional disks 
+that cannot be associated with any of the twin crystal lattice appear on DPs (Fig. 2(c-e)). 
+For instance, in the third type of DP only reflections on the line in the growth direction and 
+on the same line as the (22̅4̅) and (11̅1) reflections appear and are well separated from 
+each other (Fig. 2(c)).  
+In a fourth type of DP, an additional disks generation arises for each reflection on 
+the line of reflections corresponding to the growth direction (Fig. 2(d)). Nevertheless, the 
+recognition of individual reflections is still possible for this type of DP. The last type of DPs, 
+presented in Fig. 2(e), is the most difficult for the analysis. This is due to the overlapping 
+and smearing of the major part of the disks. This applies especially to a series of (111) 
+reflections. This effect significantly limits the number of reflections that can be used for 
+strain mapping. 
+Based on the appearance of different types of DPs and on the positions of the 
+particular reflections on the DPs a map of twins distribution of the investigated NW 
+segment is obtained (Fig. 2(k)). The blue and brown regions on the map correspond to the 
+twin A and B, respectively (Fig. 2(i,j)). The orange color on this image refers to the area 
+that cannot be described to any of the twins and belongs to one of the types of DPs 
+presented on the Fig. 2(b-e). This map presented in Fig. 2(k) is used in our further 
+considerations, in the algorithm for the determination of the crystal orientation.  
+In spite of the complexity of the data, it is possible to determine the positions of 
+diffraction disks and, as result, to perform the strain mapping. For this purpose we use 
+(22̅4̅) and (11̅1) reflections. In addition to the fact, that those reflections allow the direct 
+insight into the strain in the radial and axial direction, they are common for both twins types 
+and can be well resolved even for the “intermixed” DPs. 
+ 
+
+ 
+Figure 2 Results of NBED analysis of core-shell ZnTe/(Cd,Zn)Te NW. (a) Typical nanobeam 
+electron diffraction pattern with indicated growth direction and some of the reflections. (b-d) Four 
+types difficult to analyze diffraction patterns were found in the experimental data. (f, g) Maps of 
+relative lattice change are calculated by using (22̅4̅) reflection for radial and (11̅1) reflection for 
+axial direction respectively. (h) The map of in-plane component of NW’s bending received using 
+(22̅4̅) reflection. (i, j) NBED patterns correspond to twin A and twin B respectively. (k) Map of the 
+twins distribution in the NW. For intermixed regions features corresponding to both twins A and B 
+appear simultaneously. 
+ 
+The results of strain mapping reveal a strong radial asymmetry of the lattice 
+parameters (Fig. 2(f) and 2(g)). This observation is consistent with EDX data 
+demonstrating an inhomogeneous (Cd,Zn)Te shell thickness. There are no significant 
+discontinuities or strain jumps in the NW axial direction visible on the maps associated to 
+
+(a)
+(b)
+(c)
+(224)
+Bending
+(224)
+(220)
+(111)
+(111)
+9224
+(000)
+(000)
+(002)
+(111)
+9111
+Growthdirection
+(d)
+(e)
+(224)
+(002)
+(220)
+(111)
+(000) (111)
+(000)
+(f)
+(g)
+(h)
+1
+(i)
+7.8 deg
+224
+(k)
+7.5deg
+0.07
+0.07
+10
+0.015
+2（111)
+Twin A
+（220)
+5deg
+(002)
+0.025
+TwinA
+Intermixed
+0.023
+(i)
+(224)?
+7.5deg
+-0.02
+-0.02
+-2
+(deg)
+(220)
+0
+3deg
+（002)
+(111)
+TwinB
+0.035
+Twin B
+o degthe presence of twins. On the other hand, the radial strain map 𝜀𝑟
+𝑟𝑒𝑙 representing lattice 
+change in the direction perpendicular to the NW axis, shown in Fig. 2(f), reveals a region 
+of a distinct increase of the strain up to 3-3.5%. This strain step occurs in the radial 
+direction of the NW and is present along the NW growth axis within the entire investigated 
+NW segment. The region characterized by strain jump corresponds well to the boundary 
+between the core and shell. Therefore, the above described 𝜀𝑟
+𝑟𝑒𝑙 - map can be used to 
+estimate the diameter and position of NW-core with respect to the NW center. The 
+presence of only one strain jump on the 𝜀𝑟
+𝑟𝑒𝑙 map reflects the highly asymmetric nature of 
+the shell thickness. It can be concluded that the almost entire shell is present on the left 
+side of the NW while on the right side either bare ZnTe or a significantly thinner (Cd,Zn)Te 
+shell is present.  
+The axial 𝜀𝑎
+𝑟𝑒𝑙 strain map shown in Fig. 2(g) is characterized by a certain noise. 
+There are two reasons for this: the first one is the smaller value of g vector for (11̅1) 
+reflection compared to (22̅4̅) and, as result, the larger impact of uncertainties related to the 
+determination of its position on the DP. The second reason is related to the difficulties of 
+the determination the (11̅1) disk position on some DPs, e.g., on DPs shown in the Fig. 
+2(e). Despite of the presence of some noise, a relatively smooth lattice change is clearly 
+visible on the map shown in Fig. 2(g). We attribute this lattice distortion to the bending of 
+the NW since the core and shell crystal lattices are coherent in the axial direction and no 
+strain in the axial direction is expected. 
+ 
+ 
+Figure 3 (a) Lattice distortion map calculated according to Eq. (3). (b) The average profile 
+calculated for the dashed region on (a) 
+ 
+According to the data presented in Fig. 2, slightly larger strain values are observed 
+for the radial than for the axial strain. This means that a variation of lattice parameters in 
+the NW is larger for radial direction as compared to axial direction. This result can be 
+understood in terms of a quasi 2D misfit strain acting on the shell in the core-shell 
+
+(a)
+(b)
+0.008
+Dra
+0.03
+0.004
+0.000
+0.016
+-0.004
+-0.02
+0.008
+0
+10
+20
+30
+40
+50
+60
+Position (nm)geometry [32]. In order to characterize the value of the lattice distortion, the following 
+simple equation describing the tetragonal deformation is used: 
+𝐷𝑟𝑎 = 𝜀𝑟 − 𝜀𝑎  
+(3) 
+where 𝐷𝑟𝑎 is the lattice distortion, 𝜀𝑟 and 𝜀𝑎 are radial and axial strain respectively. The 
+lattice distortion map calculated by Eq. (3) is presented in Fig. 3(a), where the core-shell 
+geometry of the NW is clearly reproduced. It should be noted that the values in Fig. 3 
+represent relative lattice distortion with respect to a reference region, and 𝐷𝑟𝑎 = 0 doesn't 
+necessarily correspond to the lattice without tetragonal deformation. Nevertheless, the 
+results presented in Fig. 3 provide information about the character and range of the lattice 
+distortion. According to the average profile presented in Fig. 3(b) determined for the 
+dashed region of the distortion map (Fig. 3(a)), the relative lattice distortion reaches values 
+up to 1.6%. The dependence of relative tetragonal distortion on the radial position of the 
+nanowire can be well reproduced by the calculations in terms of the elastic theory (see the 
+Electronic Supplementary Material (ESM) Fig. S1). 
+In addition to the strain maps, also the map of the in-plane component (in-plane of 
+view) for lattice bending 𝛼∥ is obtained (Fig. 2(h)) based on diffraction patterns. To 
+determine this parameter the change in azimuthal angular position of (22̅4̅) disk with 
+respect to (000) beam is measured (Fig. 2(a,i,j)). Although 𝛼∥ value reflects the bending of 
+(22̅4̅) crystal plane it can also be applied for the description of the bending of the [11̅1] NW 
+growth axis. The choice of the (22̅4̅) reflection for this purpose is explained by the error 
+minimization. For the investigated 235 nm long NW segment the in-plane NW bending of 
+about 8 degrees is observed (Fig. 2(h)). The result agrees well with STEM data, where 
+NW’s bending is also clearly visible.  
+To summarize, based only on the diffraction disks positions on NBED pattern, it is 
+possible to calculate relative axial and radial strain components, quasi tetragonal lattice 
+distortion, and the in-plane components of the lattice bending. However, additional 
+information can be obtained from the analysis of intensity redistribution within the DP and 
+within individual diffraction disks. 
+ 
+5. Orientation mapping 
+This section describes a procedure for mapping of the local crystal orientation in 
+three dimensions (3D). For convenience, according to the Cartesian coordinate system, 
+three bend angles 𝛼∥, 𝛼⊥, 𝛼𝑡 are chosen to characterize the local crystallographic 
+orientation of the NW. The in-plane component of lattice bending 𝛼∥ was determined in the 
+previous section based on the in-plane rotation of DPs by following the position of the 
+(22̅4̅) reflection. This component represents an angle of unit cell rotation in the plane 
+
+perpendicular to the electron probe. The other two angles 𝛼⊥, 𝛼𝑡 correspond to the 
+bending components toward [11̅1] growth axis and angle of twist of the crystal lattice 
+around [11̅1] axis (Fig. 4), respectively. The last two components are similar to 𝛼 and 𝛽 tilt 
+angles that are used in TEM for specimen orientation and can be also named off-axis 
+angles. 
+All bend angles are determined relative to some reference values. As the reference 
+for 𝛼∥ the crystal orientation of most bottom part of the NW is chosen. In the case of 𝛼⊥ 
+and 𝛼𝑡 the perfect [110] zone axis orientation is chosen as the reference. 
+ 
+ 
+Figure 4. The scheme represents the definition of the misorientation angles. 𝛼∥ – angle denotes 
+the in-plane component of lattice bending and 𝛼⊥, 𝛼𝑡 – out-of-plane components. The sign “+” and 
+“-” represents the bend direction. 
+ 
+While the in-plane component of lattice bending (𝛼∥) causes the rotation of the 
+diffraction patterns, the out-of-plane component leads to the redistribution the reflections 
+intensity on diffraction patterns (Fig. 5(a-d)). However, the effect of the Ewald sphere 
+intersects the reciprocal lattice, which is sensitive to both, sample tilt and thickness. This 
+fact is used for a detailed study of the experimental diffraction data and to obtain local 
+crystal orientation maps of the investigated object. The idea of the determination of the 
+crystal orientation at a given position of the electron beam relies on the comparison of the 
+experimental data to a set of simulated patterns for various tilt angles.  
+For a given material there is only one crystal orientation near the zone axis that 
+corresponds to a specific diffraction pattern. That is why a full pattern matching technique 
+assisted with a cross-correlation procedure can be used for the determination of the off-
+axis angles 𝛼⊥ and 𝛼𝑡 for each experimental point based on the cross-correlation maps, as 
+exemplified in Fig. 5(e). However, some geometric transformations are required prior to 
+
+e-probethe application of pattern matching technique. They require the previously calculated 
+strain, in-plane orientation and twinning maps. Transformation of experimental patterns 
+(instead a simulated one) was used for decreasing computation time. In the case the twin 
+type cannot be clearly defined (intermixing region on the twinning map) the pattern 
+matching procedure is performed for both twins. Then, angles 𝛼⊥ and 𝛼𝑡 for the twin with a 
+higher correlation index are further considered. 
+ 
+ 
+Figure 5. (a), (b) – Regions of reciprocal space close to (000) for on-axis and off-axis conditions, 
+respectively. The diffraction pattern is formed due to the intersection of the relrods by the Ewald 
+sphere (c), (d). (a) – zone axis condition provides a quite uniform intensity distribution between 
+diffraction disks as shown on (c). (b) – off-axis condition causes the vanishing of some diffraction 
+disks as shown on (d). (e) – exemplary correlation map for one of the experimental diffraction 
+patterns. 
+ 
+As mentioned above, the intensity distribution on DP for a given crystal depends not 
+only on crystal orientation but also on the crystal thickness. Therefore, for the precise 
+
+a
+(b)
+k
+(c)
+(d)
+(e)
+0.5
+Correlation index
+0.9
+2
+X
+α=-0.4°,α,=1.3°
+(deg)
+0
+To
+-1
+-2
+-2
+-1
+0
+2
+αt (deg)crystal orientation mapping the pattern matching procedure is performed for various 
+simulated crystal thicknesses. As a result, 3D stacks of correlation maps are obtained. 
+Each (x,y,z) position on the stack corresponds to off-axis angles 𝛼⊥, 𝛼𝑡 and crystal 
+thickness, respectively. Thus, along with mapping 𝛼⊥, 𝛼𝑡 it is also possible to estimate the 
+thickness (t) of the NW at each experimental point. To perform a more precise crystal 
+thickness mapping a relatively large electron probe converge angle would be required. 
+This would, however, significantly complicate the diffraction disks recognition and, as 
+result, worsen the strain mapping. 
+The results of crystal orientation maps and the map of the estimated NW thickness 
+are presented in Fig. 6. Despite some noise in the data, a clear tendency is found on each 
+map. According to the definition of the off-axis angles, the region of NW for which 𝛼⊥ and 
+𝛼𝑡 are equal 0 corresponds to [110] zone axis orientation.  
+ 
+ 
+Figure 6 The results of the pattern matching procedure: (a) - thickness map. (b), (c) - maps of out-
+of-plane components of bending 𝛼⊥ and twisting components 𝛼𝑡 respectively. (d) The average 
+profile of 𝛼𝑡 calculated for the dashed region on (c) 
+ 
+
+(a)
+(b)
+(c)
+α
+(deg)
+(deg
+(nm)
+80
+2
+(d)
+0.0
+-0.3
+(deg)
+αt
+-0.6
+&
+-0.9
+-1.2
+0
+10
+20
+30
+40
+50
+60
+Position (nm)It is worth reminding that all maps represent a projection on the plane of view which 
+is important for their interpretation. That is why we may conclude that according to results 
+presented in Fig. 6 the top part of investigated NW’s fragment is bent with respect to 
+bottom part of about 4.1 degrees in the direction perpendicular to the plane of view. The 
+"minus" sign on the 𝛼⊥ map defines the direction of the detected bending according to Fig. 
+4 and points that the NW is bent in the direction of the electron beam propagation. Special 
+attention should be paid to the out-of-plane twisting component map 𝛼𝑡, Fig. 6(c). This 
+map represents the average value of (110) planes tilt in the radial direction of the NW (or 
+the twist [11̅1] growth direction). A negative value is interpreted as tilting of (110) planes to 
+the left, with respect to the position of the NW shown in Fig. 6. The averaged profile of 𝛼𝑡 
+for the least noisy area on the map is presented in Fig. 6(d). Interestingly, this value is not 
+constant and has the tendency to change in the radial direction. This observation means 
+that a complex lattice distortion is present in the asymmetric core-shell NW.  
+ 
+ 
+Figure 7. Simulation results of the crystal lattice performed in the frame of the finite element 
+method (FEM) for core-shell NW with diameter ~12nm with the a displacements multiplied by the 
+factor of four for clarity reasons. (a) the crystalline model of a cross-section slice across a strained 
+core-shell NW, (b) slice shown in (a) tilted toward [11̅1] direction 
+ 
+For the purposes of the proper interpretation of 𝛼𝑡 map and for the understanding of 
+the crystal lattice distortion, the crystalline model of strained core-shell NW was built. The 
+first step was creating solid core-shell NW model and calculation of three-dimensional 
+strain distribution by using COMSOL software. The simulation is performed for a NW with 
+a relatively small diameter of about ~12 nm so that the size of the simulated data is not too 
+large, and allows us to observe the bending of crystal planes into the NW. In the next step, 
+the crystalline model was built using FEM-simulated results in self-made software. The 
+displacement field components (ux, uy, uz) are multiplied by the factor of four for better 
+visibility of the lattice distortion in the crystalline model. A thin NW cross-section slice 
+resulting from the model calculations is shown in Fig. 7. For a better visibility of the crystal 
+plane bending the same slice is presented from two different angles of view: from the top, 
+Fig. 7(a), and after tilting, Fig. 7(b). These calculations confirm that 𝛼𝑡 value depends on 
+
+a)
+[111]
+(q)
+Cd
+[110]
+2
+Te
+1
+[112] 
+[110]
+Zn
+e-beamthe radial position on the bent asymmetric core-shell NW. Accordingly, the experimental 𝛼𝑡 
+map (Fig. 6(c)) represents a projection of complex 3D lattice distortion of the NW. 
+Obtained results confirm qualitatively the nonlinear behavior of the angle of twist on the 𝛼𝑡 
+map. 
+ 
+6. FEM simulation 
+The experimental data of strain and orientation mapping are used for 3D 
+reconstruction of the NW geometry and 3D strain distribution. The simulation of the strain 
+distribution is performed based on the linear elastic approach. Moreover, it is performed in 
+the frame of continuum mechanics approximation neglecting the discrete nature of 
+crystalline structure. 
+For the scopes of our simulations the total radius of the core-shell NW and the 
+elemental composition of the core, which is pure ZnTe, are fixed. At the beginning stage, 
+elemental composition of the shell equal to Cd0.6Zn0.4Te determined from TEM study was 
+also fixed in the model. However, as will be shown below, the elemental shell composition 
+can be found by the fitting procedure. The core taper in the model is chosen to be the 
+same as for the NW determined experimentally from TEM data. The radius of the core, r, 
+and its relative position with respect to the center of NW (x,y) are parameters that can be 
+found by fitting the experimental strain and orientation maps to the model calculations. The 
+fitting procedure starts with the considerations of in-plane 𝛼∥ and out-of-plane 𝛼⊥ bending 
+only. We find, in particular, that the core radius, r, and the core position (x,y) with respect 
+to the NW center determine unambiguously the specific NW bending for a given Cd 
+concentration in the shell, Eq.(4).  
+ 𝑟𝑖 = 𝑓(𝑥𝑖, 𝑦𝑖)  
+(4) 
+Therefore, for each shell composition (Cd content was chosen in the range 0.4-0.8) 
+a set of core radii with corresponding (x,y) positions, that cause the specific NW bending 
+are obtained. The details of the determination procedure of (x,y) positions of the core are 
+described in the ESM Fig. S2. In the next step, the comparison of experimental to FEM 
+simulated projected strain maps allows us to find a suitable core radius of the NW. In our 
+case, the radial strain map 𝜀𝑟, Fig. 2(f), which contains region of a sharp strain gradient, is 
+sufficiently characteristic to perform this procedure. It is established that according to the 
+fitting procedure the elemental composition of the shell can also be determined. (This is 
+due to the fact that the maximal value and behavior of strain on radial 𝜀𝑟 and axial 𝜀𝑎 maps 
+depends on content of cadmium in the shell, radius and position of the core.) Cd-content in 
+(Cd,Zn)Te shell determined by FEM simulation amounts to 0.57±0.05 which is in good 
+agreement with the EDX data. 
+
+Based on FEM modelling, the best fit is obtained for the geometric model in which 
+ZnTe core is fully covered by (Cd,Zn)Te shell. However, this result does not explain well 
+the experimental 𝜀𝑟 strain map for which only one core-shell transition region is observed, 
+Fig. 2(f). 
+This effect can be explained by the presence of 4-5 nm thick amorphous layer, 
+which covers the entire NW (Fig. 1(b)). This layer is not visible on the strain maps obtained 
+by NBED and the elastic parameters of this shell are unknown. We associate this 
+amorphous layer to the surface oxidation of the NW. Amorphization of the thin (Cd,Zn)Te 
+shell covering ZnTe core on the right side of the studied NW could be the reason for the 
+absence of the second strain jump (closer to NW surface) on experimental data. For the 
+simplicity reasons, this layer is not included in the FEM model. However, it may explain the 
+fact that the simulated data obtained for regions close to the NW surface may not be 
+comparable with the experiment due to the insensitivity of NBED to the presence of the 
+amorphous layer. 
+The geometric values obtained by the fitting procedure are: the core radius of 17±1 
+nm at the bottom part of the NW, the NW core position with respect to the NW center, 
+x=−4.5±0.5 nm, y=8.7±0.5 nm. Importantly, the performance of the above described fitting 
+procedure makes it possible to reconstruct geometry, 3D strain field and orientation for the 
+studied NW. 
+The results of FEM simulation are presented in Fig. 8. It is found that stresses with 
+the values up to a few gigapascals may occur within the NW Fig. 8(b). The stress along 
+with the asymmetric core-shell geometry causes significant bending of the NW. Maps of in-
+plane 𝛼∥ and out-of-plane 𝛼⊥ bending components (Figs. 8(c, d)) are in good agreement 
+with experimental ones (Fig. 2(h), 6(b)).  
+The core-shell geometry induces a complex three-dimensional strain distribution, 
+the projection of which we observe on the experimental strain maps. The calculated 
+projections of radial and axial strain, based on FEM simulated 3D strain distribution, are 
+presented in Fig. 8(e,f). The simulated data confirms the presence sharp strain jump on 
+experimental 𝜀𝑟
+𝑟𝑒𝑙 map and a smooth strain change for 𝜀𝑎
+𝑟𝑒𝑙 in the radial direction. The 
+behavior of 𝜀𝑎
+𝑟𝑒𝑙 map confirms that NW's shell and core crystal structures are coherent in 
+the axial direction. The observed axial strain change is caused by the bending of the NW. 
+Simultaneously, 𝜀𝑟 jump indicates the transition from the core to the shell region on the 
+map. The presence of a somewhat smoothed jump on the experimental map may be 
+explained by the presence of a topological variation, such as roughness, of the NW core.  
+ 
+
+ 
+Figure 8 FEM simulation results. (a) The initial model of asymmetric (Cd,Zn)Te/ZnTe core-
+shell NW. (b) FEM calculated von Mises stress. (c, d) – maps of in-plane 𝛼∥ and out-of-
+plane 𝛼⊥ components of the NW’s bending. (e, f) – normalized radial 𝜀𝑟
+𝑟𝑒𝑙 and axial 𝜀𝑎
+𝑟𝑒𝑙 
+strain projection maps respectively. (g–i) – calculated relative strain in terms of ZnTe bulk 
+value. (j–l) calculated absolute strain in terms of relaxed ZnTe core and Cd0.57Zn0.43Te 
+shell values. 
+ 
+In addition to projection maps, 3D FEM modeling gives us an opportunity to look 
+inside NW heterostructure and receive information concerning hidden dimensions that 
+
+(a)
+ZnTe
+(b)
+(c)
+(d)
+(e)
+(f)
+von Mises stress
+7.8
+-2.3
+Io
+αl
+200
+(Cd,Zn)Te
+x109
+10
+4
+0.07
+0.07
+5
+3.5
+0.015
+0.015
+0.025
+2
+0.04
+100
+0
+3
+0.025
+0.5
+(Pa)
+0.03
+三
+0
+Z
+-2
+-4
+[112]
+(deg)
+(deg)
+-0.02
+-0.02
+X
+0
+1110]
+y
+-20
+(nm) 40
+0
+0
+1.8
+(g)
+(h)
+(i)
+0.08
+0.08
+0.05
+-0.005
+0.005
+0.015
+0.05
+04
+0
+0
+0.005
+0.02
+-0.005
+0.01
+0.025
+0
+0.03
+0.03
+0.035
+0.035
+0.03
+0.35
+0.03
+0.04
+0.035
+-0.04
+0.035
+-0.04
+0.04
+0
+1
+[110]
+[110]
+X
+e-beam
+e-beam
+X
+e-beam
+(0)
+EZz
+abs
+-0.02
+-0.01
+0.04
+0.04
+0.04
+0.015
+-0.015
+-0.005
+0.005
+0.005
+0
+0
+0.02
+-0.01
+0.005
+0.005
+0.01
+-0.005
+0.025
+-0.005
+0.005
+-0.005
+0.005
+0
+0
+0
+-0.01
+0.01
+0.005
+0.005
+0
+-0.005
+-0.05
+-0.05
+2
+y
+0.05
+[110]
+0
+[110]
+e-beam
+e-beam
+X
+e-beamcannot be directly observed by single zone axis TEM data. For example, a cross-sectional 
+strain distribution is useful for a comprehensive study of the strain behavior in core-shell 
+NW. The cross-section maps of relative strain calculated using relaxed ZnTe as a 
+reference, at 150 nm NW height, are presented in Fig. 8(g-i). This strain representation 
+allows for tracking the tendency of the lattice changes in the NW. Significant lattice 
+changes were observed on each of the relative strain map. 𝜀𝑥𝑥
+𝑟𝑒𝑙 and 𝜀𝑦𝑦
+𝑟𝑒𝑙 map, which 
+corresponds to radial strain, demonstrates the complex behavior of the lattice change. 
+According to 𝜀𝑧𝑧
+𝑟𝑒𝑙 map the core and shell crystal lattices are coherent in the z (growth) 
+direction, whereas the gradual strain change is caused by the NW bending. 
+At the same time, the absolute strain (Fig. 8(j-l)) is advantageous for the 
+determination electrical and optical properties of the object. Regarding to 3D FEM results 
+the core undergoes smaller radial deformation compared to the shell (Fig. 8(j,k)). At the 
+same time, ZnTe core is under a significant axial tension (Fig. 8(l)). 
+ 
+5. Summary 
+In conclusion, we developed an approach for strain and orientation mapping of a 
+single nano-object containing twin boundaries and a large thickness gradient. This has 
+been achieved by a comprehensive study of scanning nanobeam electron diffraction data 
+accompanied by a theoretical simulations and the pattern matching technique. The 
+proposed approach is implemented for precise strain and orientation mapping with an 
+ultimate spatial resolution of 2.82×3.91 nm pixel size in our case, however, can be easily 
+improved to electron probe size – of about 1.3 nm, and angular resolution of about 0.1 
+degrees for curved (Cd,Zn)Te/ZnTe core-shell NW.  
+Using for acquisition an ordinary NBED data (without beam precession) has 
+enabled us to conserve also dynamical effects on diffraction patterns, which are used for 
+the estimation of local thickness of the object. However, performing a more accurate 
+thickness mapping would require a larger electron probe convergence angles.  
+It has been experimentally established and confirmed by finite element modeling 
+that asymmetric core-shell geometry introduces complex behaviors of lattice distortion, 
+which appears as a twist component of lattice bending on the projected experimental 
+maps. Obtained strain and crystallographic orientation data are introduced into the finite 
+element modeling for the reconstruction of 3D strain distribution in the NW. The proposed 
+approach can be used for performing low-dose quasi-tomography experiment on strained 
+core-shell nanowires (for example in the case of beam-sensitive materials or if tilting the 
+sample in a holder is limited). 
+ 
+
+Acknowledgment 
+This work was partly supported by the Polish National Science Centre through 
+grants No. 2016/21/B/ST5/03411, 2017/26/E/ST3/00253, and UMO-2019/35/B/ST5/03434. 
+ 
+Electronic Supplementary Material: Supplementary material (FEM modeling of relative 
+tetragonal distortion for (Cd,Zn)Te/ZnTe core-shell NW, and the details of the 
+determination procedure of (x,y) positions of the ZnTe core) is available in the online 
+version of this article at http://dx.doi.org/********. 
+ 
+Notes: The authors declare no competing financial interest. 
+ 
+ 
+ 
+
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+GaAs/InSb Core-Shell Nanowires. Nanoscale 2017, 9, 18392–18401. 
+[36] 
+Hassan, A. Al; Davtyan, A.; Küpers, H.; Lewis, R. B.; Bahrami, D.; Bertram, F.; Bussone, G.; Richter, 
+C.; Geelhaar, L.; Pietsch, U. Complete Structural and Strain Analysis of Single GaAs/(In,Ga)as/GaAs 
+
+Core–Shell–Shell Nanowires by Means of in-Plane and out-of-Plane X-Ray Nanodiffraction. J. Appl. 
+Crystallogr. 2018, 51, 1387–1395. 
+[37] 
+Kryvyi, S.; Kret, S.; Wojnar, P. Precise Strain Mapping of Nano-Twinned Axial ZnTe/CdTe Hetero-
+Nanowires by Scanning Nanobeam Electron Diffraction. Nanotechnology 2022, 33, 195704. 
+[38] 
+LeBeau, J. M.; Findlay, S. D.; Allen, L. J.; Stemmer, S. Position Averaged Convergent Beam Electron 
+Diffraction: Theory and Applications. Ultramicroscopy 2010, 110, 118–125. 
+[39] 
+Honglong, S.; Minting, L.; Wenzhong, W. CBED Tools for Semi-Automatic Measurement of Crystal 
+Thicknesses. J. Appl. Crystallogr. 2017, 50, 313–319. 
+[40] 
+Viladot, D.; Véron, M.; Gemmi, M.; Peiró, F.; Portillo, J.; Estradé, S.; Mendoza, J.; Llorca-Isern, N.; 
+Nicolopoulos, S. Orientation and Phase Mapping in the Transmission Electron Microscope Using 
+Precession-Assisted Diffraction Spot Recognition: State-of-the-Art Results. J. Microsc. 2013, 252, 
+23–34. 
+[41] 
+Ophus, C.; Zeltmann, S. E.; Bruefach, A.; Rakowski, A.; Savitzky, B. H.; Minor, A. M.; Scott, M. C. 
+Automated Crystal Orientation Mapping in Py4DSTEM Using Sparse Correlation Matching. Microsc. 
+Microanal. 2022, 28, 390–403. 
+[42] 
+AlHassan, A.; Abboud, A.; Cornelius, T. W.; Ren, Z.; Thomas, O.; Richter, G.; Micha, J. S.; Send, S.; 
+Hartmann, R.; Struder, L.; et al. Energy-Dispersive X-Ray Micro Laue Diffraction on a Bent Gold 
+Nanowire. J. Appl. Crystallogr. 2021, 54, 80–86. 
+[43] 
+Verch, A.; Côté, A. S.; Darkins, R.; Kim, Y. Y.; Van De Locht, R.; Meldrum, F. C.; Duffy, D. M.; 
+Kröger, R. Correlation between Anisotropy and Lattice Distortions in Single Crystal Calcite Nanowires 
+Grown in Confinement. Small 2014, 10, 2697–2702. 
+[44] 
+Kaleta, A.; Kret, S.; Sanchez, A. M.; Bilska, M.; Kurowska, B.; Szczepańska, A.; Płachta, J.; Wojnar, 
+P.; Wojciechowski, T. TEM Study of the Structural Properties of Nanowires Based on Cd, Zn, Te 
+Grown by MBE on Silicon Substrates. Acta Phys. Pol. A 2017, 131, 1399–1405. 
+[45] 
+Mitchell, D. R. G. Circular Hough Transform Diffraction Analysis: A Software Tool for Automated 
+Measurement of Selected Area Electron Diffraction Patterns within Digital MicrographTM. 
+Ultramicroscopy 2008, 108, 367–374. 
+[46] 
+Koch, C. Determination of Core Structure Periodicity and Point Defect Density along Dislocations. 
+Ph.D. Dissertation, Arizona State University, Phoenix, AZ, USA, 2002. 
+ 
+
+Graphical Table of Contents 
+ 
+ 
+This study concerns the development of a method for strain and orientation mapping of 
+strained highly-asymmetric core-shell nanowire based on transmission electron 
+microscopy data involving single zone axis diffraction pattern. An approach is based on the 
+symbiosis of comprehensive analysis of scanning nanobeam electron diffraction data and 
+finite element method simulation which allow for a full reconstruction of the three-
+dimensional strain field in the nanowire. 
+ 
+ 
+
+e-probe
+F
+EM
+simulation
+Full pattern
+3Dreconstruction
+Disk
+suonisod:
+20
+(nm) 40Electronic Supplementary Material 
+Reconstruction of three-dimensional strain field in an asymmetrical 
+curved core-shell hetero-nanowire 
+ 
+Serhii Kryvyi1,*, Slawomir Kret1 and Piotr Wojnar1 
+1Institute of Physics Polish Academy of Sciences, al. Lotnikow 32/46, 02-668 Warsaw, 
+Poland 
+ 
+E-mail: kryvyi@ifpan.edu.pl 
+ 
+ 
+ 
+Fig. S1 Relative tetragonal distortion for (Cd,Zn)Te/ZnTe core-shell NW calculated by FEM. (a) 
+Projection of tetragonal distortion on yz plane (perpendicular to electron beam). The pink line 
+represents the distortion profile across the NW. (b) Tetragonal distortion profile across the NW. As 
+the background was set a cross-section (xy cut) of tetragonal distortion data. Clearly visible that 
+geometric features of the NW cause extremums on the tetragonal distortion profile. 
+ 
+In Fig. S1, FEM calculated data of relative tetragonal distortion for (Cd,Zn)Te/ZnTe 
+core-shell NW according to Eq. 3 is presented. In order to compare simulated and 
+experimental data, the radial and axial strain components, 𝜀𝑦𝑦 and 𝜀𝑧𝑧, were chosen 
+respectively. Both simulated 𝜀𝑦𝑦 and 𝜀𝑧𝑧 strain components were calculated with respect to 
+ZnTe bulk value. As shown on Fig. S1b, the tetragonal distortion profile reflects geometric 
+features of the NW (in particular the core position). The calculated tetragonal distortion 
+
+(a)
+(b)
+0.06
+Dra
+Dra
+0.05
+Dra
+0.07
+0.07
+0.04
+0.03
+0.02
+0.01
+0.00
+0.028
+1-0.06
+-0.04
+-0.01
+-
+X:
+--
+Z
+-0.02
+0
+10
+20
+30
+40
+50
+60
+y
+Position (nm)profile (Fig. S1b) agrees well with the experimental one (Fig. 3b). The range of lattice 
+distortion in the middle part of the FEM simulated profile (transition core-shell region) 
+reaches 2.8%. This value is somewhat larger than obtained in the experiment (1.6%), 
+which may be explained by surface roughness and smaller sharpness of ZnTe core 
+corners in the studied NW.  
+ 
+ 
+Fig. S2 The determination of the core position (x,y) within the NW. (a) – isolines showing the 
+relationship between the core position of the radius of 17 nm in the NW and bent angles 𝛼∥ (blue 
+line) and 𝛼⊥ (red line). Those lines' intersection corresponds to the bent NW's core position. (b) – 
+the scheme of the asymmetric core-shell NW. 
+ 
+The procedure of determining the core position is based on finding two isolines on 
+the (x,y) plot, that correspond to the bending of the NW by 𝛼∥=7.8 degrees and 𝛼⊥=4.1 
+degrees respectively (Fig. S2a). The intersection of those lines provides information on the 
+exact core position (x,y). This position depends on both Cd-content in CdxZn1-xTe shell and 
+core radius. As a result, the core positions were determined for each simulated Cd-content 
+and the core radius. In the next step, the comparison of experimental to FEM simulated 
+projected strain maps allows us to find a suitable core radius and Cd-content of the NW. 
+
+(a
+(b)
+rcore=17 nm
+α,=4.1 deg
+13
+Position y (nm)
+ZnTe
+11
+(-4.5;8.7)
+(0;0)
+(-4.5;8.7)
+6
+α=7.8 deg
+(Cd,Zn)Te
+7
+2
+5
+[110]
+e-beam
+-10
+-8
+-6
+-4
+-2
+0
+Position x (nm)
\ No newline at end of file
diff --git a/_tE5T4oBgHgl3EQfSQ5r/content/tmp_files/load_file.txt b/_tE5T4oBgHgl3EQfSQ5r/content/tmp_files/load_file.txt
new file mode 100644
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@@ -0,0 +1,1377 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf,len=1376
+page_content='Reconstruction of three-dimensional strain field in an asymmetrical  curved core-shell hetero-nanowire  Serhii Kryvyi1,*, Slawomir Kret1 and Piotr Wojnar1  1Institute of Physics Polish Academy of Sciences, al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Lotnikow 32/46, 02-668 Warsaw,  Poland  E-mail: kryvyi@ifpan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='pl  Abstract  Crystal orientation and strain mapping of an individual curved and asymmetrical  core-shell hetero-nanowire is performed based on transmission electron microscopy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' It  relies on a comprehensive analysis of scanning nanobeam electron diffraction data  obtained for 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='3 nm electron probe size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The proposed approach handles also the problem  of appearing twinning defects on diffraction patterns and allows for investigation of  materials with high defect densities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' On the basis of the experimental maps and their  comparison to finite element simulations, a hidden core-shell geometry and full three-  dimensional strain distribution within the curved core-shell nanowire are obtained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As  effect, a low-dose quasi-tomography data using only single zone axis diffraction  experiment is received.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Our approach is applicable also for electron beam sensitive  materials for which performing conventional tomography is a difficult task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Keywords: strain mapping, orientation mapping, nanobeam electron diffraction, 3D  strain reconstruction, quasi-tomography, nanowire.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Headlines:  Unique approach for strain and orientation mapping within a single nano-object with  defects  Strain and orientation mapping of single curved highly-asymmetric core-shell  nanowire  A detailed description of the method for 3D strain reconstruction in core-shell  nanowire based on single zone axis diffraction pattern and its comparison to finite element  method simulation  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Introduction  Epitaxial hetero-nanowires (NWs) represent a novel technological platform with a  wide range of applications in nanotechnology, covering a number of electronic and  photonic devices, as well as sensors [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Among others, the core-shell NWs have attracted  a great deal of attention for their applications in future nanodevices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Implementation of  core-shell geometry allows for the enhancement of the light extraction efficiency from light-  emitting diodes (LEDs), a significant increase of light absorption in solar cells, and an  effective electric field control of electric current in transistors resulting in a considerable  improvement of the device performance [2]–[4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The presence of the shell may additionally  result in the enhancement of optical emission intensity from the NW-cores, as  demonstrated for GaAs/(Ga,In)P [5] and (Zn,Mn)Te/(Zn,Mg)Te core/shell nanowires [6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Moreover,  the  core-shell  NWs  are  promising  building  block  for  nanoelectromechanical systems (NEMS) [7],[8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, due to the lattice mismatch  between the core and the shell semiconductor, the core-shell configuration introduces a  relatively complex anisotropic three-dimensional (3D) lattice distortion in contrast to two-  dimensional (2D) tetragonal distortion typical for thin epilayers deposited on a thick lattice-  mismatched substrate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This principally different behavior originates from the relatively  small lateral dimensions of the NWs and the large surface-to-volume ratio typical for these  structures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  For axial NW heterostructures, it is well known that the critical thickness increases  with decreasing NW’s radius [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the case of radial NW heterostructures the situation is  more complex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In particular, the contribution of surface and interface energy significantly  affects the strain relaxation mechanism in core-shell NW heterostructures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Therefore, it is  more appropriate to use the concept of critical dimensions instead of only one critical  thickness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The NW critical dimensions: NW length, core radius, and shell thickness,  depend on each other [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Moreover, they are also affected by NW crystallographic  orientation and the presence of facets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Significant strain fields that occur in lattice mismatched core-shell NWs can cause  the formation of lattice defects, misfit dislocation in most cases, and surface morphological  transformations, such as stress-driven surface roughening [11]–[13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In addition, the  influence of the core cross-section shape on the strain field in core-shell NWs has been  reported [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Importantly, core-shell NWs are very sensitive to radial inhomogeneity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Even  small asymmetry of the shell composition or NW-core decentering leads to the occurrence  of noticeable asymmetric strain fields and, as result, bending of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This bending  reduces stresses in the NW heterostructure and, thus, leads to the avoidance of defect  formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Strain fields that inevitably occur in lattice mismatched core-shell NWs have a  significant impact on their optoelectronic properties and, in spite of the potential formation  of defects, can be used to fine-tune effectively the band gap energy [15]–[18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Moreover,  the radial core-shell geometry of the NW heterostructures gives rise to the realization of a  number of crystalline coherent structures unobtainable in classic planar configuration  [19],[20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' These findings motivate the investigation of strain fields in core-shell hetero-  NWs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Understanding and prediction of the strain relaxation mechanism is crucial for the  development of novel and the improvement of the quality of existing hetero-NW based  devices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Therefore, a significant number of papers is dedicated to the study of strain  distribution within core-shell NWs has appeared [13],[21]–[36].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Among different experimental techniques, only X-ray synchrotron and transmission  electron microscopy (TEM) based methods provide an opportunity for strain mapping with  a sufficiently high spatial resolution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Our previous report has shown that using scanning  nanobeam electron diffraction (NBED) in TEM allows us to overcome the difficulties  related to NW thickness variations and twinning of a crystal structure [37] and leads to the  realization of precise 2D strain maps of axial NW heterostructures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Our approach does not  employ the precession of electron beam, but it makes possible the conservation of  dynamical effects on diffraction pattern (DP) during acquisition of experimental data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  dynamical features in diffraction disks, for instance, can be effectively used for specimen  thickness determination with nanometer precision [38],[39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The purpose of this study is to use the intensity distribution of reflections together  with their position for the realization of crystal orientation maps in addition to strain maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  To achieve this goal, the so-called template matching technique is applied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' It relies on the  comparison of each experimental diffraction pattern to the database of pre-simulated  dynamical DPs for different misorientation angles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As an effect, the crystalline orientation  mapping is performed with unusually high resolution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Those results allow us to reveal  quasi-tomography data of a core-shell NW and to conduct a full reconstruction of the strain  field within an individual complex nano-object.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  A similar approach described previously used the commercial ASTAR software (by  Nanomegas) to recognize the phase and crystal orientation in polycrystalline materials  [40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In that case the kinematical electron diffraction approximation has been employed to  generate the template database.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' A recent paper reported using a dynamic approach for  orientation mapping [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, those approaches rely on the precession of electron  beam for collecting of experimental data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Those limitations impair the angular resolution for  the crystal orientation mapping.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' While a typical angular resolution of 1 degree is well  enough for a polycrystalline sample it is not sufficient for a monocrystalline object which is  subject of our present study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  For the investigation of a single monocrystalline NW the use of X-ray micro Laue  diffraction [42] and selected area electron diffraction (SAED) [43] for local lattice  orientation and strain profiling along the NW axis have been reported.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Both approaches  are characterized by an order of magnitude better angular resolution for local lattice  orientation as compared to the previously mentioned kinematical approach [40], but the  spatial resolution remains poor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Therefore, a new approach is required to map small  angles of misorientation for single-crystal objects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In this work, we study the strain distribution in radial (core-shell) NW  heterostructures by a conventional TEM technique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' NBED is used for the relative lattice  mapping with picometer precision and a few nanometers spatial resolution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In addition to  the lattice mapping, the pattern matching technique provides additional information about  the sample such as its thickness and local crystallographic orientation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The proposed  approach allows us, therefore, to obtain local crystallographic orientation mapping with  ultimate precision up to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='1 degree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The obtained data are used to create realistic finite  element method (FEM) models to perform full three dimensional tomography  reconstruction of strain field in radial NW heterostructure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Methods  The ZnTe/(Cd,Zn)Te core-shell NWs were grown on (111)-oriented Si substrate by  molecular beam epitaxy (EPI 620 system) with the use of Au nano-catalysts employing the  vapor–liquid–solid (VLS) growth mechanism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 1-nm-thick gold layer was pre-deposited on  the Si substrate and heated up to 450°C to induce the formation of Au-Si liquid nano-  droplets which serve as catalysts for the further ZnTe NWs growth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (Cd,Zn)Te shells are  deposited after the reduction of the substrate temperature to 350°C, at which the catalyst  droplets are frozen leading to the epitaxial overgrowth of ZnTe NWs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The detailed growth  procedure is almost the same as described in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' [44].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Structural investigations and elemental composition characterization were  performed using an objective lens corrected FEI Titan Cubed 80-300 microscope  operating at 300 kV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For the TEM examination, the NWs were transferred mechanically by  sliding a copper grid covered with holey carbon film across the sample surface with NWs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  High-resolution transmission microscopy (HR-TEM) images were acquired by Gatan  Ultrascan 1000 charge coupled device (CCD) camera.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For high-resolution scanning  transmission electron microscopy (HR-STEM) in annular dark field mode, the high-angle  annular dark-field (HAADF) Fischione 3000 detector was used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nanobeam electron  diffraction (NBED) mapping of (Cd,Zn)Te/ZnTe hetero-NW was performed in STEM mode  using the Gatan Ultrascan 1000 camera with binning 4 to increase the dynamic range and  to reduce a blooming effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Diffraction patterns were acquired with a convergence semi-  angle of 1 mrad and a probe size of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='3 nm [37].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The integration time for NBED acquisition  was chosen to be 100 msec per frame.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Energy dispersive X-ray spectroscopy (EDX) data  were collected in TEM by EDAX 30 mm2 Si(Li) detector with a collection angle of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='13  srad.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The analysis of NBED data was performed by a scripting procedure using  DigitalMicrograph software.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' To obtain precise strain maps with subpixel accuracy the  circular Hough transform was implemented in the script [37],[45].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The pattern matching  technique to correlate experimental diffraction patterns and simulated data was used to  obtain local orientation maps of bent NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Since NBED data was collected for [110] zone  axis, the orientation mapping in our case is based on the determination of crystallographic  misorientation of the NW with respect to [110] zone axis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The procedure is based on a  cross-correlation algorithm and is also implemented in the DigitalMicrograph script.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  simulation of tilt series was performed using QSTEM software which is based on a  dynamical approach and a multislice algorithm [46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' A set of misoriented DPs was  simulated for [110] ZnTe crystal misoriented in in the range from -4 to 4 degrees towards  [001] and [11̅0] crystallographic directions with step of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02 degrees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' These tilt series were  simulated for crystal thicknesses up to 80 nm with the step of 1 nm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The finite element method (FEM) modeling of (Cd,Zn)Te/ZnTe core-shell NW was  performed by COMSOL Multiphysics software.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The 3D model was developed based on the  measured geometric characteristics of NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The model consists of ZnTe NW-core  surrounded by an asymmetric (Cd,Zn)Te shell.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Crystallographic orientation and anisotropy  of Young modulus [37] were also taken into account in the model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The simulated NW has  the shape of a hexagonal frustum with the height of 235 nm and the length of the bottom  face edge of 30 nm and that of the top face of 25 nm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The last two numbers can be  roughly considered as radii of the NW on the bottom and top bases, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' To  eliminate surface relaxation effects on the bottom and top NW bases additional segments  with 50 nm height were added to these bases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' These additional parts were not considered  in the analysis of the simulated data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Structural studies  EDX elemental mapping of a typical ZnTe/(Cd,Zn)Te NW segment confirms the  radial character of the NW heterostructure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, an asymmetry in the shell thickness  occurs, which is confirmed by the irregular radial distribution of cadmium across the  measured NW heterostructure (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 1(b)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The average Cd content, x, in CdxZn1-xTe shell  determined by EDX is about 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='6±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='05.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the core-shell configuration the asymmetrical  shell and the relatively large lattice misfit between ZnTe core and (Cd,Zn)Te shell leads to  a significant bending of the NW (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 1(a)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As a result, atomic columns within this NW  heterostructure are also bent having as a consequence that the standard geometrical  phase analysis (GPA) method is not applicable for monitoring lattice changes on a large  fragment of this sample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nevertheless, the HR-TEM/STEM investigations evidenced an  epitaxial growth of the (Cd,Zn)Te shell on the ZnTe core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' No misfit dislocations between  the core and the shell were observed, whereas the crystalline structure of the shell is  exactly the same as the crystalline structure of the NW core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Twin boundaries propagating  from the core to the shell without any discontinuity were observed (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 1(b)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In addition, a  thin 4-5 nm amorphous layer on the NW surface is present.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' We associate it to the  oxidation of NWs in the air, which is confirmed by the increased oxygen content on the  surface found in EDX data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a) The High Angle Annular Dark Field image of ZnTe/(Cd,Zn)Te core-shell NW  measured in [110] zone axis;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' the rectangle represents an area investigated by nanobeam electron  diffraction (NBED).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b) HR-TEM image of a typical NW segment;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' dashed lines indicate the  hypothetical position of ZnTe core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The red and blue line profiles represent the intensities of CdL  and ZnK lines from EDX spectra averaged across the NW, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The inset represents the  schematic image of an asymmetric core-shell NW cross-section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Strain mapping  Diffraction patterns for (Cd,Zn)Te/ZnTe radial NW heterostructure were acquired as  a grid of scans recorded point by point, line by line, and finally as a 3D stack.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  (a)  (q)  [111]  [110]  [112]  ZnTe  Cd,Zn)Te shell  ZnTe core  (Cd,Zn)Te  (Cd,Zn)Teshell  Zn  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5nm  Cd  10nm  [112]  [110]  50nmacquisition area with a sampling of 24 px in the radial and 60 px in the axial direction of the  NW was used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The pixel size was 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='82 nm and 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='91 nm for x and y directions,  respectively, leading to the total area with dimensions 67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='6×235 nm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Diffraction patterns  were recorded for each electron beam position, thus, the final experimental stack consists  of 1440 diffraction patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  NBED was used to analyze the local crystal lattice deformation, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=', to perform the  strain mapping of the core-shell NW heterostructure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For this reason, the scripting  procedure written in DigitalMicrograph software was used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This procedure consists of  finding the distance 𝒈ℎ𝑘𝑙 between (000) disk and a diffraction disk with (hkl) indexes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  choice of disk that corresponds to diffraction from a certain crystal plane allows for  mapping of the interplanar spacing for specific crystallographic directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Typically, the  relative strain is introduced into this procedure:  𝜀ℎ𝑘𝑙  𝑟𝑒𝑙 =  𝑑ℎ𝑘𝑙  𝑒𝑥𝑝−𝑑ℎ𝑘𝑙  𝑟𝑒𝑓  𝑑ℎ𝑘𝑙  𝑟𝑒𝑓  (1)  where 𝑑ℎ𝑘𝑙  𝑒𝑥𝑝 and 𝑑ℎ𝑘𝑙  𝑟𝑒𝑓 are an experimental and reference interplanar spacing value for (hkl)  lattice planes respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Or in terms of reciprocal space, using |𝒈ℎ𝑘𝑙|~  1  𝑑ℎ𝑘𝑙, Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (1) can  be written as:  𝜀ℎ𝑘𝑙  𝑟𝑒𝑙 =  |𝒈ℎ𝑘𝑙  𝑟𝑒𝑓|−|𝒈ℎ𝑘𝑙  𝑒𝑥𝑝|  |𝒈ℎ𝑘𝑙  𝑒𝑥𝑝|  (2)  where 𝒈ℎ𝑘𝑙  𝑒𝑥𝑝 and 𝒈ℎ𝑘𝑙  𝑟𝑒𝑓 are an experimental and reference distance between (000) and (hkl)  disk, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As the reference, an experimentally obtained value is usually used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As a  result, a strain map represents lattice change with respect to a reference area on the map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In our considerations, we have chosen an area with maximal g value (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' minimal value of  interplanar spacing) as the reference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, in the case of core-shell NW, it also may  be useful to use other reference values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For example, the absolute strain 𝜀𝑎𝑏𝑠 can be  calculated using the relaxed value of core and shell lattice as a reference for the core and  shell region, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  It should be noted, that information obtained by NBED is averaged along the  electron nanobeam path.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' That is why the strain maps represent projections of lattice  change on the image plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nevertheless, maps can also be a function of electron probe  defocus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In our case however, the latter effect can be neglected due to the large depth of  field typical 1 mrad convergent probe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This significantly simplifies strain appearance  represented on maps compared to complicated real 3D behaviors of the lattice plane in  asymmetric core-shell NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Prior to performing the strain mapping, one has to link the crystallographic  directions and the geometry of the NW (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(a)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(a), the  identification of (22̅4̅) and (11̅1) reflections lead us to determine directly radial 𝜀𝑟  𝑟𝑒𝑙 and  axial 𝜀𝑎  𝑟𝑒𝑙 strain in NW, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Please note, that in the case of our measurements we  have the insight into the strain component perpendicular to the electron beam only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' That is  why the radial strain 𝜀𝑟  𝑟𝑒𝑙 in our considerations is restricted to this component only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Importantly, a large number of crystal twins typical for (Cd,Zn)Te structure makes it  difficult to analyze NBED data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' According to analyzed NBED data, several types of DP can  be found on the experimental stack.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The first one is a regular pattern, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  2(a), there are no difficulties to analyze such DP.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The second type represents a pattern in  which the diffraction from both twins appears simultaneously (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(b)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In this case the  electron probe reaches a region that is close to the twin boundary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The situation is more complex in the case of the other three types.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Additional disks  that cannot be associated with any of the twin crystal lattice appear on DPs (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(c-e)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  For instance, in the third type of DP only reflections on the line in the growth direction and  on the same line as the (22̅4̅) and (11̅1) reflections appear and are well separated from  each other (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(c)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In a fourth type of DP, an additional disks generation arises for each reflection on  the line of reflections corresponding to the growth direction (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(d)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nevertheless, the  recognition of individual reflections is still possible for this type of DP.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The last type of DPs,  presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(e), is the most difficult for the analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This is due to the overlapping  and smearing of the major part of the disks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This applies especially to a series of (111)  reflections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This effect significantly limits the number of reflections that can be used for  strain mapping.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Based on the appearance of different types of DPs and on the positions of the  particular reflections on the DPs a map of twins distribution of the investigated NW  segment is obtained (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(k)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The blue and brown regions on the map correspond to the  twin A and B, respectively (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(i,j)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The orange color on this image refers to the area  that cannot be described to any of the twins and belongs to one of the types of DPs  presented on the Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(b-e).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This map presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(k) is used in our further  considerations, in the algorithm for the determination of the crystal orientation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In spite of the complexity of the data, it is possible to determine the positions of  diffraction disks and, as result, to perform the strain mapping.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For this purpose we use  (22̅4̅) and (11̅1) reflections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In addition to the fact, that those reflections allow the direct  insight into the strain in the radial and axial direction, they are common for both twins types  and can be well resolved even for the “intermixed” DPs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 2 Results of NBED analysis of core-shell ZnTe/(Cd,Zn)Te NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a) Typical nanobeam  electron diffraction pattern with indicated growth direction and some of the reflections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b-d) Four  types difficult to analyze diffraction patterns were found in the experimental data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (f, g) Maps of  relative lattice change are calculated by using (22̅4̅) reflection for radial and (11̅1) reflection for  axial direction respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (h) The map of in-plane component of NW’s bending received using  (22̅4̅) reflection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (i, j) NBED patterns correspond to twin A and twin B respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (k) Map of the  twins distribution in the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For intermixed regions features corresponding to both twins A and B  appear simultaneously.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The results of strain mapping reveal a strong radial asymmetry of the lattice  parameters (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(f) and 2(g)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This observation is consistent with EDX data  demonstrating an inhomogeneous (Cd,Zn)Te shell thickness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' There are no significant  discontinuities or strain jumps in the NW axial direction visible on the maps associated to  (a)  (b)  (c)  (224)  Bending  (224)  (220)  (111)  (111)  9224  (000)  (000)  (002)  (111)  9111  Growthdirection  (d)  (e)  (224)  (002)  (220)  (111)  (000) (111)  (000)  (f)  (g)  (h)  1  (i)  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8 deg  224  (k)  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5deg  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='07  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='07  10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='015  2（111)  Twin A  （220)  5deg  (002)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='025  TwinA  Intermixed  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='023  (i)  (224)?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5deg  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  2  (deg)  (220)  0  3deg  （002)  (111)  TwinB  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='035  Twin B  o degthe presence of twins.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' On the other hand, the radial strain map 𝜀𝑟  𝑟𝑒𝑙 representing lattice  change in the direction perpendicular to the NW axis, shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(f), reveals a region  of a distinct increase of the strain up to 3-3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This strain step occurs in the radial  direction of the NW and is present along the NW growth axis within the entire investigated  NW segment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The region characterized by strain jump corresponds well to the boundary  between the core and shell.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Therefore, the above described 𝜀𝑟  𝑟𝑒𝑙 - map can be used to  estimate the diameter and position of NW-core with respect to the NW center.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  presence of only one strain jump on the 𝜀𝑟  𝑟𝑒𝑙 map reflects the highly asymmetric nature of  the shell thickness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' It can be concluded that the almost entire shell is present on the left  side of the NW while on the right side either bare ZnTe or a significantly thinner (Cd,Zn)Te  shell is present.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The axial 𝜀𝑎  𝑟𝑒𝑙 strain map shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(g) is characterized by a certain noise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  There are two reasons for this: the first one is the smaller value of g vector for (11̅1)  reflection compared to (22̅4̅) and, as result, the larger impact of uncertainties related to the  determination of its position on the DP.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The second reason is related to the difficulties of  the determination the (11̅1) disk position on some DPs, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=', on DPs shown in the Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  2(e).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Despite of the presence of some noise, a relatively smooth lattice change is clearly  visible on the map shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(g).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' We attribute this lattice distortion to the bending of  the NW since the core and shell crystal lattices are coherent in the axial direction and no  strain in the axial direction is expected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 3 (a) Lattice distortion map calculated according to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b) The average profile  calculated for the dashed region on (a)  According to the data presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2, slightly larger strain values are observed  for the radial than for the axial strain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This means that a variation of lattice parameters in  the NW is larger for radial direction as compared to axial direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This result can be  understood in terms of a quasi 2D misfit strain acting on the shell in the core-shell  (a)  (b)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='008  Dra  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='03  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='004  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='016  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='004  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='008  0  10  20  30  40  50  60  Position (nm)geometry [32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In order to characterize the value of the lattice distortion, the following  simple equation describing the tetragonal deformation is used:  𝐷𝑟𝑎 = 𝜀𝑟 − 𝜀𝑎  (3)  where 𝐷𝑟𝑎 is the lattice distortion, 𝜀𝑟 and 𝜀𝑎 are radial and axial strain respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  lattice distortion map calculated by Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (3) is presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 3(a), where the core-shell  geometry of the NW is clearly reproduced.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' It should be noted that the values in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=" 3  represent relative lattice distortion with respect to a reference region, and 𝐷𝑟𝑎 = 0 doesn't  necessarily correspond to the lattice without tetragonal deformation." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nevertheless, the  results presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 3 provide information about the character and range of the lattice  distortion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' According to the average profile presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 3(b) determined for the  dashed region of the distortion map (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 3(a)), the relative lattice distortion reaches values  up to 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='6%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The dependence of relative tetragonal distortion on the radial position of the  nanowire can be well reproduced by the calculations in terms of the elastic theory (see the  Electronic Supplementary Material (ESM) Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In addition to the strain maps, also the map of the in-plane component (in-plane of  view) for lattice bending 𝛼∥ is obtained (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(h)) based on diffraction patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' To  determine this parameter the change in azimuthal angular position of (22̅4̅) disk with  respect to (000) beam is measured (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(a,i,j)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Although 𝛼∥ value reflects the bending of  (22̅4̅) crystal plane it can also be applied for the description of the bending of the [11̅1] NW  growth axis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The choice of the (22̅4̅) reflection for this purpose is explained by the error  minimization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For the investigated 235 nm long NW segment the in-plane NW bending of  about 8 degrees is observed (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(h)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The result agrees well with STEM data, where  NW’s bending is also clearly visible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  To summarize, based only on the diffraction disks positions on NBED pattern, it is  possible to calculate relative axial and radial strain components, quasi tetragonal lattice  distortion, and the in-plane components of the lattice bending.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, additional  information can be obtained from the analysis of intensity redistribution within the DP and  within individual diffraction disks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Orientation mapping  This section describes a procedure for mapping of the local crystal orientation in  three dimensions (3D).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For convenience, according to the Cartesian coordinate system,  three bend angles 𝛼∥, 𝛼⊥, 𝛼𝑡 are chosen to characterize the local crystallographic  orientation of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The in-plane component of lattice bending 𝛼∥ was determined in the  previous section based on the in-plane rotation of DPs by following the position of the  (22̅4̅) reflection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This component represents an angle of unit cell rotation in the plane  perpendicular to the electron probe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The other two angles 𝛼⊥, 𝛼𝑡 correspond to the  bending components toward [11̅1] growth axis and angle of twist of the crystal lattice  around [11̅1] axis (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 4), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The last two components are similar to 𝛼 and 𝛽 tilt  angles that are used in TEM for specimen orientation and can be also named off-axis  angles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  All bend angles are determined relative to some reference values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As the reference  for 𝛼∥ the crystal orientation of most bottom part of the NW is chosen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the case of 𝛼⊥  and 𝛼𝑡 the perfect [110] zone axis orientation is chosen as the reference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The scheme represents the definition of the misorientation angles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 𝛼∥ – angle denotes  the in-plane component of lattice bending and 𝛼⊥, 𝛼𝑡 – out-of-plane components.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The sign “+” and  “-” represents the bend direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  While the in-plane component of lattice bending (𝛼∥) causes the rotation of the  diffraction patterns, the out-of-plane component leads to the redistribution the reflections  intensity on diffraction patterns (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 5(a-d)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, the effect of the Ewald sphere  intersects the reciprocal lattice, which is sensitive to both, sample tilt and thickness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This  fact is used for a detailed study of the experimental diffraction data and to obtain local  crystal orientation maps of the investigated object.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The idea of the determination of the  crystal orientation at a given position of the electron beam relies on the comparison of the  experimental data to a set of simulated patterns for various tilt angles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  For a given material there is only one crystal orientation near the zone axis that  corresponds to a specific diffraction pattern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' That is why a full pattern matching technique  assisted with a cross-correlation procedure can be used for the determination of the off-  axis angles 𝛼⊥ and 𝛼𝑡 for each experimental point based on the cross-correlation maps, as  exemplified in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 5(e).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, some geometric transformations are required prior to  e-probethe application of pattern matching technique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' They require the previously calculated  strain, in-plane orientation and twinning maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Transformation of experimental patterns  (instead a simulated one) was used for decreasing computation time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the case the twin  type cannot be clearly defined (intermixing region on the twinning map) the pattern  matching procedure is performed for both twins.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Then, angles 𝛼⊥ and 𝛼𝑡 for the twin with a  higher correlation index are further considered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a), (b) – Regions of reciprocal space close to (000) for on-axis and off-axis conditions,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The diffraction pattern is formed due to the intersection of the relrods by the Ewald  sphere (c), (d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a) – zone axis condition provides a quite uniform intensity distribution between  diffraction disks as shown on (c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b) – off-axis condition causes the vanishing of some diffraction  disks as shown on (d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (e) – exemplary correlation map for one of the experimental diffraction  patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  As mentioned above, the intensity distribution on DP for a given crystal depends not  only on crystal orientation but also on the crystal thickness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Therefore, for the precise  a  (b)  k  (c)  (d)  (e)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5  Correlation index  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='9  2  X  α=-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='4°,α,=1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='3°  (deg)  0  To  1  2  2  1  0  2  αt (deg)crystal orientation mapping the pattern matching procedure is performed for various  simulated crystal thicknesses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As a result, 3D stacks of correlation maps are obtained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Each (x,y,z) position on the stack corresponds to off-axis angles 𝛼⊥, 𝛼𝑡 and crystal  thickness, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Thus, along with mapping 𝛼⊥, 𝛼𝑡 it is also possible to estimate the  thickness (t) of the NW at each experimental point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' To perform a more precise crystal  thickness mapping a relatively large electron probe converge angle would be required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  This would, however, significantly complicate the diffraction disks recognition and, as  result, worsen the strain mapping.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The results of crystal orientation maps and the map of the estimated NW thickness  are presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Despite some noise in the data, a clear tendency is found on each  map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' According to the definition of the off-axis angles, the region of NW for which 𝛼⊥ and  𝛼𝑡 are equal 0 corresponds to [110] zone axis orientation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 6 The results of the pattern matching procedure: (a) - thickness map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b), (c) - maps of out-  of-plane components of bending 𝛼⊥ and twisting components 𝛼𝑡 respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (d) The average  profile of 𝛼𝑡 calculated for the dashed region on (c)  (a)  (b)  (c)  α  (deg)  (deg  (nm)  80  2  (d)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='3  (deg)  αt  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='6  &  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='9  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='2  0  10  20  30  40  50  60  Position (nm)It is worth reminding that all maps represent a projection on the plane of view which  is important for their interpretation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' That is why we may conclude that according to results  presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 6 the top part of investigated NW’s fragment is bent with respect to  bottom part of about 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='1 degrees in the direction perpendicular to the plane of view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  "minus" sign on the 𝛼⊥ map defines the direction of the detected bending according to Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  4 and points that the NW is bent in the direction of the electron beam propagation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Special  attention should be paid to the out-of-plane twisting component map 𝛼𝑡, Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 6(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This  map represents the average value of (110) planes tilt in the radial direction of the NW (or  the twist [11̅1] growth direction).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' A negative value is interpreted as tilting of (110) planes to  the left, with respect to the position of the NW shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The averaged profile of 𝛼𝑡  for the least noisy area on the map is presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 6(d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Interestingly, this value is not  constant and has the tendency to change in the radial direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This observation means  that a complex lattice distortion is present in the asymmetric core-shell NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Simulation results of the crystal lattice performed in the frame of the finite element  method (FEM) for core-shell NW with diameter ~12nm with the a displacements multiplied by the  factor of four for clarity reasons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a) the crystalline model of a cross-section slice across a strained  core-shell NW, (b) slice shown in (a) tilted toward [11̅1] direction  For the purposes of the proper interpretation of 𝛼𝑡 map and for the understanding of  the crystal lattice distortion, the crystalline model of strained core-shell NW was built.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  first step was creating solid core-shell NW model and calculation of three-dimensional  strain distribution by using COMSOL software.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The simulation is performed for a NW with  a relatively small diameter of about ~12 nm so that the size of the simulated data is not too  large, and allows us to observe the bending of crystal planes into the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the next step,  the crystalline model was built using FEM-simulated results in self-made software.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  displacement field components (ux, uy, uz) are multiplied by the factor of four for better  visibility of the lattice distortion in the crystalline model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' A thin NW cross-section slice  resulting from the model calculations is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For a better visibility of the crystal  plane bending the same slice is presented from two different angles of view: from the top,  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 7(a), and after tilting, Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 7(b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' These calculations confirm that 𝛼𝑡 value depends on  a)  [111]  (q)  Cd  [110]  2  Te  1  [112]  [110]  Zn  e-beamthe radial position on the bent asymmetric core-shell NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Accordingly, the experimental 𝛼𝑡  map (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 6(c)) represents a projection of complex 3D lattice distortion of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Obtained results confirm qualitatively the nonlinear behavior of the angle of twist on the 𝛼𝑡  map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' FEM simulation  The experimental data of strain and orientation mapping are used for 3D  reconstruction of the NW geometry and 3D strain distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The simulation of the strain  distribution is performed based on the linear elastic approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Moreover, it is performed in  the frame of continuum mechanics approximation neglecting the discrete nature of  crystalline structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  For the scopes of our simulations the total radius of the core-shell NW and the  elemental composition of the core, which is pure ZnTe, are fixed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' At the beginning stage,  elemental composition of the shell equal to Cd0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='6Zn0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='4Te determined from TEM study was  also fixed in the model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, as will be shown below, the elemental shell composition  can be found by the fitting procedure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The core taper in the model is chosen to be the  same as for the NW determined experimentally from TEM data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The radius of the core, r,  and its relative position with respect to the center of NW (x,y) are parameters that can be  found by fitting the experimental strain and orientation maps to the model calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  fitting procedure starts with the considerations of in-plane 𝛼∥ and out-of-plane 𝛼⊥ bending  only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' We find, in particular, that the core radius, r, and the core position (x,y) with respect  to the NW center determine unambiguously the specific NW bending for a given Cd  concentration in the shell, Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  𝑟𝑖 = 𝑓(𝑥𝑖, 𝑦𝑖)  (4)  Therefore, for each shell composition (Cd content was chosen in the range 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='4-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8)  a set of core radii with corresponding (x,y) positions, that cause the specific NW bending  are obtained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The details of the determination procedure of (x,y) positions of the core are  described in the ESM Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the next step, the comparison of experimental to FEM  simulated projected strain maps allows us to find a suitable core radius of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In our  case, the radial strain map 𝜀𝑟, Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(f), which contains region of a sharp strain gradient, is  sufficiently characteristic to perform this procedure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' It is established that according to the  fitting procedure the elemental composition of the shell can also be determined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (This is  due to the fact that the maximal value and behavior of strain on radial 𝜀𝑟 and axial 𝜀𝑎 maps  depends on content of cadmium in the shell, radius and position of the core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=') Cd-content in  (Cd,Zn)Te shell determined by FEM simulation amounts to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='57±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='05 which is in good  agreement with the EDX data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Based on FEM modelling, the best fit is obtained for the geometric model in which  ZnTe core is fully covered by (Cd,Zn)Te shell.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, this result does not explain well  the experimental 𝜀𝑟 strain map for which only one core-shell transition region is observed,  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  This effect can be explained by the presence of 4-5 nm thick amorphous layer,  which covers the entire NW (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 1(b)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This layer is not visible on the strain maps obtained  by NBED and the elastic parameters of this shell are unknown.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' We associate this  amorphous layer to the surface oxidation of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Amorphization of the thin (Cd,Zn)Te  shell covering ZnTe core on the right side of the studied NW could be the reason for the  absence of the second strain jump (closer to NW surface) on experimental data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For the  simplicity reasons, this layer is not included in the FEM model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, it may explain the  fact that the simulated data obtained for regions close to the NW surface may not be  comparable with the experiment due to the insensitivity of NBED to the presence of the  amorphous layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The geometric values obtained by the fitting procedure are: the core radius of 17±1  nm at the bottom part of the NW, the NW core position with respect to the NW center,  x=−4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5 nm, y=8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='7±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5 nm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Importantly, the performance of the above described fitting  procedure makes it possible to reconstruct geometry, 3D strain field and orientation for the  studied NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The results of FEM simulation are presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' It is found that stresses with  the values up to a few gigapascals may occur within the NW Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The stress along  with the asymmetric core-shell geometry causes significant bending of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Maps of in-  plane 𝛼∥ and out-of-plane 𝛼⊥ bending components (Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(c, d)) are in good agreement  with experimental ones (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2(h), 6(b)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The core-shell geometry induces a complex three-dimensional strain distribution,  the projection of which we observe on the experimental strain maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The calculated  projections of radial and axial strain, based on FEM simulated 3D strain distribution, are  presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(e,f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The simulated data confirms the presence sharp strain jump on  experimental 𝜀𝑟  𝑟𝑒𝑙 map and a smooth strain change for 𝜀𝑎  𝑟𝑒𝑙 in the radial direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=" The  behavior of 𝜀𝑎  𝑟𝑒𝑙 map confirms that NW's shell and core crystal structures are coherent in  the axial direction." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The observed axial strain change is caused by the bending of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Simultaneously, 𝜀𝑟 jump indicates the transition from the core to the shell region on the  map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The presence of a somewhat smoothed jump on the experimental map may be  explained by the presence of a topological variation, such as roughness, of the NW core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Figure 8 FEM simulation results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a) The initial model of asymmetric (Cd,Zn)Te/ZnTe core-  shell NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b) FEM calculated von Mises stress.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (c, d) – maps of in-plane 𝛼∥ and out-of-  plane 𝛼⊥ components of the NW’s bending.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (e, f) – normalized radial 𝜀𝑟  𝑟𝑒𝑙 and axial 𝜀𝑎  𝑟𝑒𝑙  strain projection maps respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (g–i) – calculated relative strain in terms of ZnTe bulk  value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (j–l) calculated absolute strain in terms of relaxed ZnTe core and Cd0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='57Zn0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='43Te  shell values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In addition to projection maps, 3D FEM modeling gives us an opportunity to look  inside NW heterostructure and receive information concerning hidden dimensions that  (a)  ZnTe  (b)  (c)  (d)  (e)  (f)  von Mises stress  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='3  Io  αl  200  (Cd,Zn)Te  x109  10  4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='07  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='07  5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='015  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='015  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='025  2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='04  100  0  3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='025  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5  (Pa)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='03  三  0  Z  2  4  [112]  (deg)  (deg)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  X  0  1110]  y  20  (nm) 40  0  0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8  (g)  (h)  (i)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='005  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='005  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content='05  2  y  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='05  [110]  0  [110]  e-beam  e-beam  X  e-beamcannot be directly observed by single zone axis TEM data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' For example, a cross-sectional  strain distribution is useful for a comprehensive study of the strain behavior in core-shell  NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The cross-section maps of relative strain calculated using relaxed ZnTe as a  reference, at 150 nm NW height, are presented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(g-i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This strain representation  allows for tracking the tendency of the lattice changes in the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Significant lattice  changes were observed on each of the relative strain map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 𝜀𝑥𝑥  𝑟𝑒𝑙 and 𝜀𝑦𝑦  𝑟𝑒𝑙 map, which  corresponds to radial strain, demonstrates the complex behavior of the lattice change.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  According to 𝜀𝑧𝑧  𝑟𝑒𝑙 map the core and shell crystal lattices are coherent in the z (growth)  direction, whereas the gradual strain change is caused by the NW bending.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  At the same time, the absolute strain (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(j-l)) is advantageous for the  determination electrical and optical properties of the object.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Regarding to 3D FEM results  the core undergoes smaller radial deformation compared to the shell (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(j,k)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' At the  same time, ZnTe core is under a significant axial tension (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 8(l)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Summary  In conclusion, we developed an approach for strain and orientation mapping of a  single nano-object containing twin boundaries and a large thickness gradient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This has  been achieved by a comprehensive study of scanning nanobeam electron diffraction data  accompanied by a theoretical simulations and the pattern matching technique.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The  proposed approach is implemented for precise strain and orientation mapping with an  ultimate spatial resolution of 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='82×3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='91 nm pixel size in our case, however, can be easily  improved to electron probe size – of about 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='3 nm, and angular resolution of about 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='1  degrees for curved (Cd,Zn)Te/ZnTe core-shell NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Using for acquisition an ordinary NBED data (without beam precession) has  enabled us to conserve also dynamical effects on diffraction patterns, which are used for  the estimation of local thickness of the object.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' However, performing a more accurate  thickness mapping would require a larger electron probe convergence angles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  It has been experimentally established and confirmed by finite element modeling  that asymmetric core-shell geometry introduces complex behaviors of lattice distortion,  which appears as a twist component of lattice bending on the projected experimental  maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Obtained strain and crystallographic orientation data are introduced into the finite  element modeling for the reconstruction of 3D strain distribution in the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The proposed  approach can be used for performing low-dose quasi-tomography experiment on strained  core-shell nanowires (for example in the case of beam-sensitive materials or if tilting the  sample in a holder is limited).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Acknowledgment  This work was partly supported by the Polish National Science Centre through  grants No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2016/21/B/ST5/03411, 2017/26/E/ST3/00253, and UMO-2019/35/B/ST5/03434.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Electronic Supplementary Material: Supplementary material (FEM modeling of relative  tetragonal distortion for (Cd,Zn)Te/ZnTe core-shell NW, and the details of the  determination procedure of (x,y) positions of the ZnTe core) is available in the online  version of this article at http://dx.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='org/********.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Notes: The authors declare no competing financial interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  References  [1]  Dasgupta, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Sun, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Liu, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Brittman, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Andrews, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Lim, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Gao, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Yan, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Yang, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Dasgupta, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 25th Anniversary Article: Semiconductor Nanowires - Synthesis,  Characterization, and Applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Adv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Mater.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2014, 26, 2137–2184.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  [2]  Mandl, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wang, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Schimpke, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Kölper, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Strain in Nanowires and Nanowire Heterostructures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' pp 79-123.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Liao, X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Extrem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Kavanagh, K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Wojciechowski, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content='  Kłopotowski;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Wojnar, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Kret, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Tech.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Mech.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Bussone, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Grifone, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Hübner, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Grenzer, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Ghorbani-Asl, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Krasheninnikov, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Kriegner, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Bahrami, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Al-  Hassan, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' MRS Adv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Miglio, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Twofold Origin of Strain-  Induced Bending in Core-Shell Nanowires: The GaP/InGaP Case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nanotechnology 2018, 29, 315703.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  [24]  Meng, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Braun, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wang, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Fenrich, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Xue, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Diercks, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Gorman, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Richard,  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Marshall, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Cai, W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Coupling of Coherent Misfit Strain and Composition Distributions  in Core–Shell Ge/Ge1-XSnx Nanowire Light Emitters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Mater.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Today Nano 2019, 5, 100026.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  [25]  Zhu, Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Svensson, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Persson, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wallenberg, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Gromov, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wernersson, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Compressively-Strained GaSb Nanowires with Core-Shell Heterostructures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nano Res.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2020, 13,  2517–2524.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  [26]  Al-Humaidi, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Feigl, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Jakob, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Schroth, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Alhassan, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Davtyan, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Herranz, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Anjum, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Novikov, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Francoual, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Nanotechnology 2021, 33, 015601.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Lewis, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Bending of GaAs–InP Core–Shell Nanowires by Asymmetric Shell  Deposition: Implications for Sensors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' ACS Appl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nano Mater.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Peng, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Marshall, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Cai, W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  McIntyre, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Bending and Precipitate Formation Mechanisms in Epitaxial Ge-Core/GeSn-Shell  Nanowires.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Nanoscale 2021, 13, 17547–17555.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Fickenscher, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Smith, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Nanotechnology 2022, 33, 195704.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Stemmer, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Position Averaged Convergent Beam Electron  Diffraction: Theory and Applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Ultramicroscopy 2010, 110, 118–125.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Minting, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wenzhong, W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' CBED Tools for Semi-Automatic Measurement of Crystal  Thicknesses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Crystallogr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 2017, 50, 313–319.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Véron, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Gemmi, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Peiró, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Portillo, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Estradé, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Mendoza, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Llorca-Isern, N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content='  Nicolopoulos, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Orientation and Phase Mapping in the Transmission Electron Microscope Using  Precession-Assisted Diffraction Spot Recognition: State-of-the-Art Results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Zeltmann, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Bruefach, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Rakowski, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Savitzky, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Minor, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Scott, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Microsc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Microanal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Abboud, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Cornelius, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Thomas, O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Richter, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Micha, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Send, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Hartmann, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Struder, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' 2021, 54, 80–86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Côté, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Darkins, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Kim, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Meldrum, F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content='  Kröger, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Correlation between Anisotropy and Lattice Distortions in Single Crystal Calcite Nanowires  Grown in Confinement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Small 2014, 10, 2697–2702.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Kret, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=' Sanchez, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
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+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Kurowska, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Szczepańska, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Płachta, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wojnar,  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Wojciechowski, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' TEM Study of the Structural Properties of Nanowires Based on Cd, Zn, Te  Grown by MBE on Silicon Substrates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Acta Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Pol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' A 2017, 131, 1399–1405.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  [45]  Mitchell, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Circular Hough Transform Diffraction Analysis: A Software Tool for Automated  Measurement of Selected Area Electron Diffraction Patterns within Digital MicrographTM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Ultramicroscopy 2008, 108, 367–374.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  [46]  Koch, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Determination of Core Structure Periodicity and Point Defect Density along Dislocations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Dissertation, Arizona State University, Phoenix, AZ, USA, 2002.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Graphical Table of Contents  This study concerns the development of a method for strain and orientation mapping of  strained highly-asymmetric core-shell nanowire based on transmission electron  microscopy data involving single zone axis diffraction pattern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' An approach is based on the  symbiosis of comprehensive analysis of scanning nanobeam electron diffraction data and  finite element method simulation which allow for a full reconstruction of the three-  dimensional strain field in the nanowire.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  e-probe  F  EM  simulation  Full pattern  3Dreconstruction  Disk  suonisod:  20  (nm) 40Electronic Supplementary Material  Reconstruction of three-dimensional strain field in an asymmetrical  curved core-shell hetero-nanowire  Serhii Kryvyi1,*, Slawomir Kret1 and Piotr Wojnar1  1Institute of Physics Polish Academy of Sciences, al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Lotnikow 32/46, 02-668 Warsaw,  Poland  E-mail: kryvyi@ifpan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='pl  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S1 Relative tetragonal distortion for (Cd,Zn)Te/ZnTe core-shell NW calculated by FEM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a)  Projection of tetragonal distortion on yz plane (perpendicular to electron beam).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The pink line  represents the distortion profile across the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b) Tetragonal distortion profile across the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As  the background was set a cross-section (xy cut) of tetragonal distortion data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Clearly visible that  geometric features of the NW cause extremums on the tetragonal distortion profile.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S1, FEM calculated data of relative tetragonal distortion for (Cd,Zn)Te/ZnTe  core-shell NW according to Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 3 is presented.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In order to compare simulated and  experimental data, the radial and axial strain components, 𝜀𝑦𝑦 and 𝜀𝑧𝑧, were chosen  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' Both simulated 𝜀𝑦𝑦 and 𝜀𝑧𝑧 strain components were calculated with respect to  ZnTe bulk value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As shown on Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S1b, the tetragonal distortion profile reflects geometric  features of the NW (in particular the core position).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The calculated tetragonal distortion  (a)  (b)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='06  Dra  Dra  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='05  Dra  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='07  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='07  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='03  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='01  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='028  1-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='01 X:  --  Z  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='02  0  10  20  30  40  50  60  y  Position (nm)profile (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S1b) agrees well with the experimental one (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' 3b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The range of lattice  distortion in the middle part of the FEM simulated profile (transition core-shell region)  reaches 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This value is somewhat larger than obtained in the experiment (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='6%),  which may be explained by surface roughness and smaller sharpness of ZnTe core  corners in the studied NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S2 The determination of the core position (x,y) within the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (a) – isolines showing the  relationship between the core position of the radius of 17 nm in the NW and bent angles 𝛼∥ (blue  line) and 𝛼⊥ (red line).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=" Those lines' intersection corresponds to the bent NW's core position." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' (b) –  the scheme of the asymmetric core-shell NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  The procedure of determining the core position is based on finding two isolines on  the (x,y) plot, that correspond to the bending of the NW by 𝛼∥=7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8 degrees and 𝛼⊥=4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='1  degrees respectively (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' S2a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' The intersection of those lines provides information on the  exact core position (x,y).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' This position depends on both Cd-content in CdxZn1-xTe shell and  core radius.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' As a result, the core positions were determined for each simulated Cd-content  and the core radius.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content=' In the next step, the comparison of experimental to FEM simulated  projected strain maps allows us to find a suitable core radius and Cd-content of the NW.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='  (a  (b)  rcore=17 nm  α,=4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='1 deg  13  Position y (nm)  ZnTe  11  (-4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='7)  (0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='0)  (-4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='7)  6  α=7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
+page_content='8 deg  (Cd,Zn)Te  7  2  5  [110]  e-beam  10  8  6  4  2  0  Position x (nm)' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/_tE5T4oBgHgl3EQfSQ5r/content/2301.05527v1.pdf'}
diff --git a/a9AzT4oBgHgl3EQf2v6K/content/tmp_files/2301.01819v1.pdf.txt b/a9AzT4oBgHgl3EQf2v6K/content/tmp_files/2301.01819v1.pdf.txt
new file mode 100644
index 0000000000000000000000000000000000000000..ff343bdea5eb93fadd5ff3e52c4da2d7555842b1
--- /dev/null
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@@ -0,0 +1,1946 @@
+A Protocol for Intelligible Interaction Between Agents That
+Learn and Explain
+Ashwin Srinivasana,∗, Michael Bainb, A. Baskarc, Enrico Coierad
+aDept. of CSIS& APPCAIR, BITS Pilani, Goa, India
+bSchool of CSE, University of NSW, Sydney, Australia
+cDept. of CSIS, BITS Pilani, Goa, India
+dCentre for Health Informatics, Macquarie University, Sydney, Australia
+Abstract
+Recent engineering developments have seen the emergence of Machine Learning (ML) as a powerful
+form of data analysis with widespread applicability beyond its historical roots in the design of
+autonomous agents. However, relatively little attention has been paid to the interaction between
+people and ML systems. Recent developments on Explainable ML address this by providing visual
+and textual information on how the ML system arrived at a conclusion. In this paper we view the
+interaction between humans and ML systems within the broader context of interaction between
+agents capable of learning and explanation. Within this setting, we argue that it is more helpful to
+view the interaction as characterised by two-way intelligibility of information rather than once-off
+explanation of a prediction. We formulate two-way intelligibility as a property of a communication
+protocol. Development of the protocol is motivated by a set of ‘Intelligibility Axioms’ for decision-
+support systems that use ML with a human-in-the-loop. The axioms are intended as sufficient
+criteria to claim that: (a) information provided by a human is intelligible to an ML system; and (b)
+information provided by an ML system is intelligible to a human. The axioms inform the design
+of a general synchronous interaction model between agents capable of learning and explanation.
+We identify conditions of compatibility between agents that result in bounded communication, and
+define Weak and Strong Two-Way Intelligibility between agents as properties of the communication
+protocol.
+Keywords:
+Learning Agents, Two-Way Intelligibility, Communication.
+∗Corresponding author
+Preprint submitted to Elsevier
+January 6, 2023
+arXiv:2301.01819v1  [cs.AI]  4 Jan 2023
+
+1. Introduction
+In the second half of his seminal 1950 paper [44], Alan Turing describes an autonomous agent
+that has the capacity to alter its programming based on experiments and mistakes. Since then,
+developments in mathematics and computing have made steady progress and one form of ML – deep
+neural networks – has been able to achieve startlingly good predictive performance when provided
+with sufficient data and computational resources.
+A difficulty has arisen when the models ML methods construct have to be examined by humans.
+For example, a deep neural network may predict, with high accuracy, the occurrence of malignancies
+from X-ray images. If an explanation of how that prediction was arrived at is required by the
+clinician, then we hit an “intelligibility bottleneck”. Some of this arises from a mismatch between
+what certain ML practitioners view as suitable explanations, and what subject end-users require [2].
+If current techniques for explanation are unfit for purpose, they relegate ML systems to the status
+of drugs for which no definitive biological mechanism is understood, but which nonetheless may be
+effective [10]. Whilst this may allow ML to be applied for some tasks, it falls short of “human-level”
+performance as far as explainability goes [4].1
+But what does it mean for an explanation from an ML-system to be understandable to the
+clinician, or, more broadly, to a person interacting with a ML- based system? One could view this
+as a requirement for humans and ML systems to maximise their mutual knowledge, developed over
+sequences of communicative interactions [5]. At least some shared understanding of the concepts
+and terminology in a domain appears to be needed for communication between human and machine,
+just as between humans. Serious consequences may follow when this is lacking, for example, in the
+misinterpretation of scientific knowledge in legal proceedings [16, 37], or when the rate of production
+and complexity of data outpaces the abilities of specialists to assimilate and process them.
+In such settings, we would expect human-machine systems to become increasingly collaborative,
+with neither human nor machine having complete answers to problems. We expect not only that
+information provided by a machine should be intelligible to a human, but also that any information
+provided by a human will need to be intelligible to the machine. In this paper, we view this ‘two-way
+intelligibility’ requirement within the broader context of two-way intelligible interaction between
+agents capable of learning and explanation.
+The main contributions of the paper are as follows:
+1. We propose the notion of Two-Way Intelligibility between agents as a pre-requisite in the
+design of Explainable Artificial Intelligence (XAI) systems. We characterise Two-Way In-
+telligibility as the consequence of the interaction between a pair of communicating agents
+capable of learning and explanation. This includes, but is not limited to, a human and an AI
+system, and provide a set of intuitive axioms to specify the special case of human-machine
+intelligibility;
+2. A detailed description of a communication protocol between agents, such that both One-Way
+and Two-Way Intelligibility can be defined as properties arising from the execution of the
+1We
+recognise
+that
+there
+are
+clinical
+settings
+where
+explanations
+may
+not
+be
+required.
+ARDA,
+for
+example,
+is
+a
+highly
+accurate
+ML-based
+tool
+for
+diagnosis
+of
+diabetic
+retinopathy
+(see:
+https://health.google/caregivers/arda/).
+based on the work reported in [12].
+It has been trained using
+labelled data provided by over 100 clinicians, and has been tested in a clinical trial. It is a device for triage-assistance
+in settings where a clinician examines 1000s of patients a day, and the tool is considered adequately field-tested. In
+this paper we are concerned instead with what needs to be done if explanations are needed.
+2
+
+protocol. We define condition of compatibility between agents under which the communication
+is bounded; and conditions under which the protocol can be seen as a correct implementation
+of the intelligibilty axioms proposed for human-machine interaction.
+The strange case of Thompson’s table
+An early description of the understandability of a machine’s explanation to a human spe-
+cialist is provided by Michie [25]. The description begins with the construction of a black
+box for a chess endgame (the interjections in brackets are ours):
+At the meeting in Toronto in 1977 of the International Federation for Informa-
+tion Processing, Kenneth Thompson of Bell Telephone Laboratories presented a
+computer program for playing the chess end-game of King and Queen against
+King and Rook. He had done this by the ultimate in ‘hammer and tongs’ meth-
+ods: in the absence of a complete set of rules for playing the end-game, he had
+previously programmed the machine to work out what to do in every single
+possible position . . . All these moves were then loaded into a gigantic ‘look-up’
+table in the machine’s memory . . . Thompson invited [International Masters] to
+demonstrate winning play for the Queen’s side against the machine. To their
+embarrassment they found they could not win, even after many attempts . . . The
+machine repeatedly conducted the defence in ways which to them were so bizarre
+and counter-intuitive [like separating King and Rook] that [the Chess Masters]
+were left grasping air . . . Naturally [they] found the experience upsetting. They
+wanted to ask the program to explain its strategy, but this of course neither it
+nor its author could do. The answer in every case was, ‘It’s in the table.’ (pg.
+64, [25])
+Michie describes how this situation is not very different to the case of ML programs that are
+unable to explain their decision-making. He sees this as not being especially problematic
+in some circumstancesa. However in some other cases, involving decision-making in critical
+areas, he notes that lack of meaningful feedback from the machine can become a serious
+issue:
+But what if the system were doing something of social importance, such as man-
+aging a complex control function in factory automation, transport or defence?
+Two supervisors, let us imagine, are responsible for intervening manually in the
+event of malfunction. The system now does the equivalent in industrial or mili-
+tary terms of ‘separating its King and Rook’. ‘Is this a system malfunction?’ the
+supervisors ask each other. They turn to the system for enlightenment. But it
+simply returns the same answer over and over again . . . Any socially responsible
+design for a system must make sure that its decisions are not only scrutable but
+refutable . . . (“The lunatic black box”, pg. 68, [25]).
+aSurprisingly, Michie includes the possibility that scientific discovery may even benefit from highly pre-
+dictive but opaque machine-constructed models, since it would force scientists to develop new explanations
+for unexpected predictions.
+3
+
+X-ray Not Covid because:
+The explanation does not mention
+Air-space opacification probability is low, and
+the right upper lobe air space
+Cardiomegaly probability is high; and
+opacification consistent with Covid
+Emphysema probability is low
+Pneumothorax probability is low
+Fibrosis probability is low
+Machine’s explanation
+Radiologist’s feedback
+Radiologist’s Opinion about the Model’s
+Explanation
+Prediction
+Correct
+Wrong
+Unsure
+Sufficient
+17
+0
+0
+Incomplete
+1
+3
+1
+Incorrect
+3
+2
+3
+Figure 1: Top: The machine’s explanation and a senior radiologist’s feedback; and Bottom: A tabulation of the
+radiologist’s assessment of explanations from the ML-based system on a set of test images.
+2. A Model for Intelligible Interaction
+We motivate the development of a general interaction model between agents that learn and
+explain by looking first at possible criteria for inferring One-Way Intelligibility of human-machine
+interaction. These criteria will then inform the design of a communication protocol for intelligible
+interaction in the more general setting.
+2.1. Specifying Intelligibility in Human-Machine Interaction
+We motivate the notion of intelligible interaction using a recent research study on identification of
+Covid-19 patients, based on X-ray images. The automated tool described in [17] uses a hierarchical
+design in which clinically relevant features are extracted from X-ray images using state-of-the-
+art deep neural networks.
+Deep neural networks are used to extract features like ground-glass
+opacity from the X-rays; and the system also includes a network for a deep network for prediction
+of possible disease (like pneumonia). The output from the deep networks are used by a symbolic
+decision-tree learner to arrive at a prediction about Covid-19. Explanations are textual descriptions
+obtained from the path followed by the decision-tree. Results reported in [17] describe how this
+neural-symbolic approach compares to an end-to-end monolithic neural approach (the predictive
+results of the two are comparable).
+However, our interest here is on the clinical assessment of
+the explanations produced by the symbolic model by radiologists: Fig. 1 shows an example of a
+machine’s explanation and a clinician’s assessment of that explanation. A tabulation of assessment
+on several “test” images is also shown. From the tabulation we can see: (a) The radiologist does
+not always think the model is correct (this is despite a supposed predictive accuracy of over 99%
+claimed for the model); (b) The radiologist is more likely to refute the explanation when he thinks
+the model is wrong; (c) Overall, the radiologist refutes the explanations in 13/30 ≈ 43% of the
+instances and finds the explanations acceptable for the remaining 17 cases (≈ 57%).
+We would like to say that the machine’s explanations are ‘intelligible’ to the human, since they
+are all either confirmed or refuted. We propose to capture this notion of intelligibility using the
+following six axioms that are concerned with communication of information in two categories:2
+2We restrict information to be in the form of prediction accompanied by an explanation. For simplicity, we refer
+4
+
+Human-to-Machine. Axioms in this category are concerned with machine-intelligibility of the
+information provided by a human to the machine.
+1. Machine-Confirmation: If the machine ratifies a human-explanation then the human’s
+explanation is intelligible to the machine.
+2. Machine-Refutability: If the machine refutes a human-explanation then the human’s
+explanation is intelligible to the machine.
+3. Machine-Performance: If the human-explanation improves machine-performance then
+the human’s explanation is intelligible to the machine.
+Machine-to-Human. This concerns the human-intelligibility of explanations provided by a ma-
+chine:
+4. Human-Confirmation: If the human ratifies a machine-explanation then the machine’s
+explanation is intelligible to the human.
+5. Human-Refutability: If the human refutes a machine-explanation then the machine’s
+explanation is intelligible to the human.
+6. Human-Performance: If the machine-explanation improves the human’s performance
+then the machine’s explanation is intelligible to the human.
+For the instances in Fig. 1, one or the other of the Human-Confirmation axiom or the Human-
+Refutability axiom will hold. Appendix Appendix A contains more examples from the ML literature
+where conditions of the axioms can be said to hold. At this point, the following clarifications may
+be helpful:
+• The examples in Appendix Appendix A are by no means the only ones in the literature. How-
+ever, some of the conditions have received less attention than the others (machine-refutability,
+and human-performance are examples);
+• The axioms are not intended to be a complete definition of machine- or human-intelligibility.
+Thus it is possible, for example, that none of the conditions for the machine-to-human axioms
+hold, and the machine’s explanation may still be human-intelligible; The axioms also do not
+specify what, if anything, should be done if one of more of them hold. For example, if a
+machine’s explanation is refuted, then what should the machine do about it?
+• Two aspects of the axioms might escape attention are: (a) Although individually, the axioms
+result in an inference of One-Way Intelligibility, but taken together they allow an inference
+of Two-Way Intelligibility; and (b) The inference of intelligibility will depend on the specific
+human and machine involved in the interaction.
+Thus, the axioms can at best be seen as a partial specification for intelligibility within the
+context of an interaction model. In the next section, we develop a general model of interaction
+between agents that use agent-specific functions for learning and explanations. We then use this
+model to identify conditions of collaborative communication between human and machine; and
+identify two-way intelligibility based on the messages exchanged. We will return in Sec. 3.3 to the
+notion of the axioms as a specification for intelligibility.
+to both as an explanation in the axioms: we disentangle these later in the paper. The constituents of explanations
+are left open: the axioms identify conditions when these constituents are intelligible to the recipient.
+5
+
+2.2. Interaction between LEX Agents
+We now develop an interaction model for the more general setting. Let A be a set of agents that
+have capabilities for learning (induction) and explanation (justification).3 We will call such agents
+LEX agents (short for Learn-and-Explain). Specifically, we assume that the interaction between
+LEX agents will be modelled by communicating finite-state automata which we will also call LEX
+automata. We will assume each LEX automaton am for the agent m has access to: a hypothesis
+Hm; and a dataset Dm consisting of 4-tuples {(xi, yi, ei, pi)}N
+i=1, where xi is a data-instance, yi is a
+label for xi; ei is an explanation for yi given xi; and pi represents the provenance for the label and
+explanation (that is, details about the origin of yi, ei for an xi). Additionally, we will assume each
+LEX automaton am also has access to the following automaton-specific functions:
+(a) PREDICTm that returns the prediction of a data-instance x using its hypothesis;
+(b) EXPLAINm that returns an explanation for a data-instance x using its hypothesis;
+(c) LEARNm that learns a possibly new hypothesis given its existing hypothesis, dataset, and a
+possibly new data-triple;
+(d) MATCHm which is true if a pair of predictions y, y′ match; and
+(e) AGREEm that is true if a pair of explanations e, e′ agree with each other.
+We call these LEX-functions. In the rest of the paper, it will be understood that these functions are
+automaton-specific and we will drop the subscript on the functions unless we want to emphasise
+them. We will return to these functions later in the paper. Additionally we will assume a special
+agent ∆ ̸∈ A, called the oracle. ∆ is a non-LEX agent, but it will be convenient to model it’s
+interaction with other LEX automata using the same communication protocol used for LEX automata.
+2.2.1. LXP: A Communication Protocol for LEX Automata
+We will adopt a protocol in which messages are exchanged between a pair of LEX automata
+am, an ∈ A in a session.4 In this paper, we will only be focusing on communication that takes
+place one-instance-at-a-time. The messages in the communication protocol follows the grammar-like
+rules shown below:
+SendMessage ::= Send(M,(T,(X,Y,E)))
+ReceiveMessage ::= Receive(M,(T,(X,Y,E)))
+Send ::= ’+’
+Receive ::= ’-’
+M ::= m, m ∈ A ∪ {∆}
+T ::= t, t ∈ {Init, Ratify, Refute, Revise, Reject, Term}
+X ::= x, x ∈ X
+Y ::= y, y ∈ Y ∪ {′?′}
+E ::= e, e ∈ E ∪ {′?′, ▲}
+Here ϵ denotes a empty string (‘do nothing’); X is a set of data-instances; Y is a set of ‘labels’ for
+data-instances, and ’?’ is to be read as “not known”; E is a set of explanations. The explanation
+▲ is to be read as ‘oracular statement”.
+3The capacity for inference (deduction) is taken for granted.
+4We will use the terms “agents” and “automata” interchangeably.
+6
+
+Figure 2(a) shows the messages sent and received by an automaton for an agent (other than ∆),
+and Fig 2(b) shows the corresponding messages sent and received by ∆. Informally, the figure tells
+us that every session between a pair of LEX automata has to explicitly initiated and terminated.
+The session can be terminated by either automaton, and an automaton can only initiate a new
+session after terminating an existing session.
+We will also require that only messages sent by ∆ can contain ▲ as an explanation and that
+the following restriction holds on the LEX functions: for any agent m ̸= ∆ and Dm, if Hm =
+LEARNm(·, Dm) and (x, y, ▲) ∈ Dm, then AGREEm(PREDICTm(x, Hm), y) = TRUE. Informally, this
+assumes the predictions by the oracle are always correct, and therefore all non-oracular agents have
+to ensure their predictions are consistent with the predictions they have received from the oracle.
+To specify the LXP protocol fully we need to define the transition system, which we describe next.
+Guarded Transitions
+Let Smn(x) denote a session between am and an in A ∪ {∆} about a data-instance x ∈ X.
+Correctly there may be multiple sessions between am,n involving the same data-instance, and we
+would need an additional index to capture this. We ignore this here, and will usually omit x, when
+the context is obvious. We also adopt the convention that the session Smn is initiated by am.
+Smn can be represented by the execution of the protocol which results in a sequence of ‘configura-
+tions’ ⟨γmn,1, γmn,2, . . . , γmn,k⟩. It is helpful to think of any configuration γmn,i as being composed of
+a pair of ‘local configurations’ of the automaton γm,i for am and γn,i for an, and γmn,i = (γm,i, γn,i).
+We will define γm,i = (sm,i, (Hm,i, Dm,i), µm,i) and γn,i = (sn,i, (Hn,i, Dn,i), µn,i). Here the s·,i are
+states; H·,i are hypotheses; D·,i are 4-tuples; µ·,i is the message sent or received. From the gram-
+mar rules, messages are of the form +(A, (t, (x, y, e))) or −(A, (t, (x, y, e)), where A is either m or
+n (denoting am or an for short); t is a message-tag, x is a data-instance, y is a label, and e is an
+explanation. The corresponding local configuration γn,i is similar.
+Before defining transitions between configurations, we introduce the guards here. The guard ⊤
+is trivially true in all configurations. The definitions of non-trivial guards are the same for all LEX
+agents, and we define them here for the receiving automaton (an).
+Definition 1 (Guards). Let an be a LEX agent.
+Let γmn,i = (γm,i, γn,i) be a configuration in
+a session Smn, where γm,i = (sm,i, (Hm,i, Dm,i), µm,i) and γn,i = (sn,i, (Hn,i, Dn,i), µn,i).
+Let
+µm,i = +(n, (tm, (x, ym, em))), µn,i = −(m, (tm, (x, ym, em))), yn = PREDICTn(x, Hn,i), and en =
+EXPLAINn((x, yn), Hn,i). Then we define the guards:
+g1: MATCHn(yn, ym) ∧ AGREEn(en, em)
+g2: MATCHn(yn, ym) ∧ ¬AGREEn(en, em)
+g3: ¬MATCHn(yn, ym) ∧ AGREEn(en, em)
+g4: ¬MATCHn(yn, ym) ∧ ¬AGREEn(en, em)
+Remark 1. We note the following:
+(a) It is not hard to see that at most one of the four guards can be true in a configuration γmn,i.
+(b) The guards only apply to the automaton in the CAN SEND state in γmn,i (here an);
+7
+
+START
+CAN RECEIVE
+CAN SEND
+END
+⊤; +(A, (Init, (X1, Y1, E1))
+⊤; −(A, (Init, (X2, Y2, E2)))
+⊤; −(A, (T, (X2, Y2, E2)))
+REV; +(A, (Revise, (X2, Y2, E′
+2)))
+REJ; +(A, (Reject, (X2, Y ′
+2, E′
+2)))
+RAT; +(A, (Ratify, (X2, Y ′
+2, E′
+2)))
+REF; +(A, (Refute, (X2, Y2, E′
+2)))
+⊤; ±(A, (Term, (X3, Y3, E3)))
+⊤; ±(A, (Term, (X2, Y2, E2)))
+START
+END
+⊤; −(A, (Init, (X1, ?, ?)))
+⊤; +(A, (Term, (X1, Y1, ▲)))
+(a)
+(b)
+Figure 2: Messages sent (’+”) and received (’-’) by: (a) automata for agents other than the oracle; and (b) the oracle.
+Here ⊤ stands for a guard condition that is trivially true. RAT, REF, REV and REJ represent the guard conditions
+used by the guarded transition system, which are described below.
+8
+
+(c) The guards for all automata use only the LEX functions MATCH and AGREE. However, since
+these functions are automaton-specific, the value of the guard function in one automaton may
+or may not agree with the corresponding value in a different automaton. We will restrict
+ourselves to the compatible automata, which we define below.
+The guards are used to define guarded transition relations (or simply transition relations). In-
+tuitively, transitions can be understood as follows: if a guard g is TRUE in a configuration after
+performing some computation then an action is executed. The action consists of receiving a message
+or sending a response (except when the received tag is Term).
+Definition 2 (Guarded Transition Relation). A guarded transition relation is a set of 4-tuples
+((γm, γn), Π, g, (γ′
+m, γ′
+n)), where γm, γn, γ′
+m and γ′
+n are (local) configurations; Π is the computations
+performed by the sending automaton5 to evaluate g and update (γm, γn) to (γ′
+m, γ′
+n). g is a Boolean
+guard function defined over local configurations.
+To address (c) in Remark. 1, we focus on the special case where a pair of LEX agents that agree
+with each other on their MATCH and AGREE functions within a session.
+Definition 3 (Compatible Automata). Let Smn be a session between LEX agents am and an. Let
+Ym = {ym : +(n, (·, (x, ym, ·))} be the set of predictions in messages sent by am to an and Yn = {yn :
++(m, (·, (x, yn, ·))} be the set of messages sent by an to am. Let Em = {em : +(n, (·, (x, ·, em))}
+be the set of explanations in messages sent by am to an and En = {en : +(m, (·, (x, ·, en)))} be
+the set of explanations in messages sent by an to am. We will say there is a functional agreement
+on predictions between am and an in Smn, or am
+≃y an in Smn, if for all ym ∈ Ym and yn ∈
+Yn, MATCHm(ym, yn) = MATCHn(yn, ym). Similarly we will say there is a functional agreement on
+explanations between am and an in Smn, or am ≃e an in Smn, if for all em ∈ Em and en ∈ En
+AGREEm(em, en) = AGREEn(en, em). We will say automata am and an are compatible in session Smn
+iff am ≃y an and am ≃e an in Smn.
+We assume that the oracle ∆ is compatible with any LEX agent.
+A session involving compatible agents will be called a collaborative session. We now examine
+transitions between automata am and an in a collaborative session. Assume automaton an receives a
+message µ from am. Then, an executes code Π; checks the guard g; updates the current configuration
+γ to a new configuration γ′; and sends a message µ′ to m. For a pair of agents am and an, neither
+of which is ∆, the transitions specify that the message sent by an to am satisfies the following
+constraints:
+Explanation
+AGREE(en, em)
+¬AGREE(en, em)
+MATCH(yn, ym)
+Ratify
+Refute or
+Prediction
+(A)
+Revise (B)
+¬MATCH(yn, ym)
+Refute or
+Reject
+Revise (C)
+(D)
+Note that in category (A), guard g1 will be true; in category (B), guard g2 will be true; in
+category (C), guard g3 will be true; and in category (D), guard g4 will be true. In addition, a
+further test (g′) will be used in (B) and (C) to decide on whether a Refute or Revise message-tag
+5The automaton which is in CAN SEND in γm or γn.
+9
+
+is sent. Appendix Appendix B lists all possible transitions involving non-trivial guard functions.
+Restricting am and an to being compatible automata eliminates some elements from the set of
+transitions.
+Definition 4 (Transitions in a Collaborative Session). Let Smn be a session between compati-
+ble agents am and an. The transitions for Smn can be specified as a set of 4-tuples (γ, Π, g, γ′).
+Let γ = ((sm, (Hm, Dm), +(n, µ)), (sn, (Hn, Dn), −(m, µ))) and γ′ = (s′
+m, ((Hm, Dm), −(n, µ′)),
+(s′
+n, (H′
+n, D′
+n), +(m, µ′))), where sm = CAN RECEIVE, sn = CAN SEND; s′
+m = CAN SEND, s′
+n =
+CAN RECEIVE.
+Let Π = (D′
+n := Dn ∪ {(x, ym, em, m)) ; P ; yn := PREDICT(x, Hn) ;
+en :=
+EXPLAIN((x, yn), Hn) ; y′
+n := PREDICT(x, H′
+n) ; e′
+n := EXPLAIN((x, y′
+n), H′
+n)). Let g′ = MATCH(y′
+n, ym)
+∧ AGREE(e′
+n, em).
+Using Proposition 2 in Appendix Appendix B, the legal transitions for an are specified below (for
+simplicity, we only show µ, P, g and µ′; the numbering of transitions is from the complete tabulation
+in Appendix Appendix B).
+Trans
+µ (received by an)
+P
+g
+µ′ (sent by an)
+0.
+No message
+H′
+n := Hn
+⊤
+(Init, (x, y′
+n, e′
+n))
+1.
+(Init, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+2.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+3.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+4.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+5.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+6.
+(Init, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+7.
+(Ratify, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+13.
+(Refute, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+14.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+15.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+16.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+17.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+18.
+(Refute, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+19.
+(Revise, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+30.
+(Reject, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+31.
+(Ratify, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+32.
+(Refute, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+33.
+(Revise, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+34.
+(Reject, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+35.
+(Init, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+36.
+(Term, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+em = ▲
+No message
+37.
+(Term, (x, ym, em))
+H′
+n := Hn
+em ̸= ▲
+No message
+The legal transitions for am can be obtained by interchanging n and m.
+In Defn. 4, we assume that Revise is sent by an only if its LEARN function can find a hypothesis
+H′
+n such that the resulting prediction y′
+n matches ym, and the resulting explanation e′
+n agrees with
+em (that is, g′ is true).
+Example 1. Let am and an be compatible automata. Suppose am initiates the transition by sending
+the message +(n, (Init, (x, ym, em))) to an. Suppose g2 ∧ ¬g′ is true for an. Then automaton an
+responds (using transtion 2) with −(m, (Refute, (x, y′
+n, e′
+n))). Suppose g3∧g′ is true for am. That is,
+10
+
+automaton can revise its hypothesis to ensure that its prediction y′
+m matches y′
+n and its explanation
+e′
+m agrees with e′
+n. Then an and sends the message +(n, (Revise, (x, y′
+m, e′
+m))) (using transition
+17). Since g1 is now necessarily true, an sends +(m, (Ratify, (x, y′, e′))) (using transition 19). am
+then terminates the session (using transition 31).
+We can construct an abstraction of the set of transitions in the form of a ‘message-graph’. This is
+in Fig. 3: for simplicity, to the row numbers in the tabulation in Defn.4.6 It is evident from the
+self-loops in the graph that communication can become unbounded. To redress this, we alter the
+LXP protocol by replacing transitions encoding self-loops.
+Definition 5 (Transitions in a Modified Protocol). From Remark 3 in Appendix Appendix
+B,
+the entries for 7 and 30 can be replaced with transitions 7′ and 30′ below. In addition, we rename
+transition 14 and 16 as 14 − k and 16 − k to denote that at most k occurrences of the transition can
+occur on any execution; and add the transitions 14′ and 16′ to allow termination after k iterations.
+The modified set of transitions are shown below.
+S.No.
+µ
+P
+g
+µ′
+7′.
+(Ratify, (x, ym, em))
+H′
+n := Hn
+g1
+(T erm, (x, y′
+n, e′
+n))
+14′.
+(Refute, (x, ym, em))
+H′
+n :=:= LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(T erm, (x, y′
+n, e′
+n))
+14-k.
+(Refute, (x, ym, em))
+H′
+n :=:= LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, (x, y′
+n, e′
+n))
+16′.
+(Refute, (x, ym, em))
+H′
+n :=:= LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(T erm, (x, yn, en))
+16-k.
+(Refute, (x, ym, em))
+H′
+n :=:= LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, (x, y′
+n, e′
+n))
+30′.
+(Reject, (x, ym, em))
+H′
+n := Hn
+g4
+(T erm, (x, y′
+n, e′
+n))
+We will call the modified protocol LXP(k). The corresponding message-graph is in Fig. 3(c).
+2.3. Protocol Properties
+It is straightforward to show that communication between compatible agents using LXP(k) is
+bounded:
+Proposition 1 (BoundedCommunication). Let Fig 3(c) represents the message graph of a col-
+laborative session using the LXP(k) protocol. Then any communication in the session has bounded
+length.
+Proof. All messages in a session commence with Init and end with Term message-tags. The result
+follows straightforwardly from the fact that fig. 3(c) is a DAG except the loops 14-k and 16-k at
+Refute. But each of these loops can occur at most k times. Therefore any path between Init and
+Term is bounded.
+We note that without the restriction to compatible agents, it is not possible to guarantee bounded
+communication (Fig. 3(a), which contains several cycles). One- and Two-Way Intelligibility can be
+stated as properties of LXP(k).
+Definition 6 (Messages sent in a Session Smn). Let Smn be a session between agents m and
+n consisting of a sequence of configurations ⟨γ1, γ2, . . . , γk⟩, where γi = (γm,i, γn,i). Let γm,i =
+6Informally, for an edge (v1, v2) in the graph, the label for v1 is the message-tag received, and the label for v2
+is the message-tag sent. The edges are labelled with the corresponding transition entries in the table in Defn.4.
+Correctly, the edge-label should be distinguish between which of an or am is sending, and which is receiving along
+with the message content. This level of detail is not needed for what follows.
+11
+
+Init
+Ratify
+ 1
+Refute
+ 2, 4
+Revise
+ 3, 5
+Reject
+ 6
+Term
+ 35
+ 7
+ 8, 10
+ 9, 11
+ 12
+ 31
+ 13
+ 14, 16
+ 15, 17
+ 18
+ 32
+ 19
+ 20, 22
+ 21, 23
+ 24
+ 33
+ 25
+ 26, 28
+ 27, 29
+ 30
+ 34
+(a)
+Init
+Ratify
+ 1
+Refute
+ 2, 4
+Revise
+ 3, 5
+Reject
+ 6
+Term
+ 35
+ 7
+ 31
+ 13
+ 14, 16
+ 15
+ 32
+ 19
+ 33
+ 30
+ 34
+(b)
+Init
+Ratify
+ 1
+Refute
+ 2, 4
+Revise
+ 3, 5
+Reject
+ 6
+Term
+ 35
+ 7', 31
+ 13
+ 14-k, 16-k
+ 15, 17
+ 18
+ 14', 16', 32
+ 19
+ 33
+ 30', 34
+(c)
+Figure 3: Message-graph obtained from: (a) transitions listed in Appendix Appendix B; (b) the transitions in the
+LXP protocol, which is only between compatible agents (Defn.4 and (c) the transitions defined in the LXP(k) protocol
+(Defn. 5, in which self-loops in LXP are removed).
+12
+
+(·, ·, µm,i), γn,i = (·, ·, µn,i) where µm,1 = +(n, (Init, ·)) and µ·,k = +(·, (Term, ·)). Then, the set
+of messages sent from m to n in Smn is Mmn = {τ : there exists i such that µm,i = +(n, τ)}. The
+set of messages sent from n to m in Smn is Mmn = {τ : there exists i such that µn,i = +(m, τ)}.
+The messages sent in a session Smn is defined as the pair (Mmn, Mnm).
+Definition 7 (One-way Intelligibility). Let (Mmn, Mnm) be the messages sent in a session Smn.
+If there exists at least one element (ti, ·) ∈ Mmn s.t. ti ∈ {Ratify, Refute, Revise} then we will say
+Smn exhibits One-Way Intelligibility for m using LXP(k). Similarly for One-Way Intelligibility for
+n.
+Definition 8 (Two-Way Intelligibility). Let (Mmn, Mnm) be the messages sent in a session Smn. If
+Smn exhibits One-Way Intelligibility for m using LXP(k) and Smn exhibits One-Way Intelligibility
+for n using LXP(k) One-Way Intelligibility for n then we will say Smn exhibits Weak Two-Way
+Intelligibility for m and n using LXP(k). If Smn exhibits Weak Two-Way Intelligibility for m and n
+using LXP(k) and there does not exist any (t, ·) ∈ Mmn ∪ Mnm s.t. t = Reject then we will say that
+Smn exhibits Strong Two-Way Intelligibility for m and n using LXP(k).
+3. Limitations and Clarifications
+Although LXP(k) gives us a basis for inferring intelligibility from interaction, it is only a first
+step. The reader would have already identified some limitations, notably:
+• Execution of LXP(k) requires definition of the LEX functions.
+As is evident from Defn. 4,
+transitions involve checks and updates that involve significant local computation. Of these
+the functions LEARN and EXPLAIN require attention. We comment on these below.
+• The description of the protocol has been substantially simplified by two assumptions. First,
+that each session will deal with one data-instance at-a-time, and secondly, that the agents
+involved in the interaction are compatible. The first restriction means that data containing
+multiple examples will require multiple sessions. While learning and revision of hypotheses
+(the LEX function LEARN) is possible with single examples, for example with an on-line learner,
+it is more likely that several sessions may be needed to arrive at a suitable hypothesis.7 An
+alternative to multiple sessions is to modify messages to include multiple instances, along
+with their predictions and explanations. This would then require all the LEX functions to be
+modified to account for this change. The issue of compatibility is related to the notion of
+‘shared knowledge’. The notion of compatibility we have used implies a shared meaning of
+when two predictions are similar, and when two explanations agree. It may be possible to
+have bounded-length sessions without this common understanding. At this stage, we do not
+know how to achieve this.
+• LXP(k) is a synchronous protocol, somewhat like a plain old telephone system (“POTS”). That
+is, interaction between a pair of agents has to be terminated before commencing a new one.
+More elaborate protocols allowing concurrency may be possible, at the expense of greater
+7A useful side-effect of single-instance sessions is that it allows the communication of instance-specific explanations
+(“this specific data instance has this label because . . . ”). It has been suggested that this is a more effective way for
+humans to convey relevant information to a machine-learning engine [27].
+13
+
+complexity in managing the global configuration of the system. It may require provenance
+information to be more detailed (like inclusion of session identifiers and session indices, along
+with the sender’s identifier).
+• The protocol does not account for noise in the channel, delays, or cost of communication
+between agents. Implementations will need to account for all of these aspects.
+Finally, although not a limitation of LXP(k), it is nevertheless useful to note that it is common for
+protocols to have a preliminary (hand-shaking) phase where some prior information is exchanged.
+We have not described this aspect in the paper, but it is the phase where LEX agents can establish
+some ‘common ground’ needed for ensuring compatibility.
+3.1. Note on LEX Functions
+The principal LEX functions are in 3 categories: (a) Inference (the function PREDICT); (b) In-
+duction (the function LEARN); and (c) Justification (the function EXPLAIN). The Boolean functions
+MATCH and AGREE are defined in terms the functions in categories (a)–(c). It is our position in this
+paper that these constitute the basic functionality needed for agents that learn and explain.
+One the face of it, it would appear that the LXP(k) protocol requires LEARN to construct hy-
+potheses one-instance at a time (that is, the protocol is restricted to on-line learners). However
+this is not the case. It is feasible that LEARN may only construct a hypothesis after a reasonable
+number of instances have been accumulated. This could be reflected, for example, in the automaton
+receiving the instances sending a sequence of messages with Refute tags, and then a message with
+a Revise tag. Thus, communicating data instance-by-instance does not necessarily mean hypothe-
+ses also have to revised instance-by-instance. Assuming that prediction is an important role for a
+hypothesis, the requirement of a PREDICT function is unsurprising. However, the MATCH function
+can still require some attention. It is straightforward if this is defined by the equality relation. But
+this may not be appropriate for some kinds of predictions like numeric values. If a pair of numeric
+values are taken to match is they are within some tolerance factor, then the definition of MATCH
+may not satisfy some intuitive properties of equality (like transitivity).
+LXP(k) requires all predictions should be accompanied by explanations.
+For some kinds of
+agents, like those based on logic, it is possible to identify EXPLAIN with some known descriptors, like
+proofs and AGREE can be formulated in terms of well-understood logical operations, like consistency
+checking. For explanations in a less formal setting, like natural language, it is likely that obtaining
+a definition of AGREE may require additional effort, and may require models constructed from data.
+Example 2. Let am and an be agents that use a logic-based representation, who have exchanged
+predicate-definitions encoding their domain-knowledge. Let Hm be the current hypothesis of am and
+Hn be the hypothesis for an. Let predictions of a data-instance x by Hm,n be done by clauses of the
+form predict(X, C) ← Body, to be read as “The prediction of any instance X is C if the conditions
+in Body are true”. Then possible LEX functions for am (and similarly for an) are;
+(a) y = PREDICTm(x, Hm) ≡ (Hm ⊢ predict(x, y)) (where ⊢ is a derivability relation);
+(b) LEARNm constructs hypotheses using techniques developed in Inductive Logic Programming
+[29];
+(c) e = EXPLAINm((x, y), Hm) is the clause in Hm used to derive predict(x, y);
+(d) If ym is a prediction by am and yn is a prediction by an then MATCHm(ym, yn) := (ym = yn);
+14
+
+(e) if em is a (clausal) explanation from am and en is a (clausal) explanation from an then
+AGREEm(em, en) := (em =θ en) (where =θ denotes an equivalence relation based on the θ-
+subsumption as defined in [31]).
+(These definitions are illustrative, and not the only ones possible with logic-based agents.)
+3.2. Role of The Oracle
+The oracle ∆ has been used as the source of infallible information about the label for any
+data instance x. In any session Sm∆, ∆ receives a message −(m, (Init, (x, ?, ?))) denoting a query
+about the label and explanation for data instance x. ∆ terminates the session with the message
++(m, (Term, (x, y, ▲))), where y is the oracle’s prediction for the label of x and ▲ denotes that the
+explanation is an oracular statement. In our interaction model, ∆ never initiates a session; and
+never sends any message-tags other than Term.
+A question that arises is this: if the true labels of data-instances can be obtained directly from
+the oracle, why doesn’t a LEX agent communicated just with ∆? One aspect we have not considered
+in developing the communication protocol is the cost of communication. Collaboration between LEX
+agents will be worthwhile if: (a) communication to and from ∆ is significantly more expensive (in
+time or money or both) than communication between LEX agents; and (b) the LEX functions of any
+one agent can use predictions and explanations from other agents effectively. Of these, (a) is likely
+to be the case if the oracle is intended to model the acquisition of real-world data by manipulation
+and experimentation. The extent to which (b) holds will depend on whether agents are able to
+establish some common knowledge, and fulfil the requirements of compatibility.
+The following example shows how collaboration can result in an effective use of either agent’s
+knowledge of the oracle’s prediction, thus possibly lessening the cost of communicating to the
+oracle.
+Example 3. Let m, n be compatible LEX agents with MATCHm(ym, yn) := (ym = yn) and MATCHn(yn, ym)
+:= (yn = ym). Let Smn(x) be a collaborative session between m and n s.t. Smn terminate with
+a Ratify message-tag(correctly, Ratify followed by Term), with Hm, Hn the hypotheses for m, n,
+and Dm, Dn be the datasets for m, n respectively. If (x, y, ▲, ∆) ∈ Dm or (x, y, ▲, ∆) ∈ Dn then
+PREDICTm(x, Hm) = PREDICTn(x, Hn) = y.
+Remark 2. If either m or n has an oracular prediction for x and the session ends with m, n
+reaching a consensus on prediction and explanation, then both agents will agree with the oracle’s
+prediction for x. This way, it is sufficient for only one of m or n to communicate to ∆ about x.
+Extending to set of instances X = {x1, x2, . . . , xk}, the cost of communicating to the oracle can be
+reduced for both m and n by restricting oracle-communication for each agent to partitions Xm and
+Xn respectively.
+3.3. LXP(k) and the Intelligibility Axioms
+We now reappraise the Intelligibility Axioms in Sec. 2.1 in terms of communication using LXP(k)
+between a human- and a machine-agent. We can treat the axioms as a specification (Spec) for
+intelligibility and the protocol as an implementation (Impl) for intelligibility. Following [15], Impl
+correctly implements Spec iff Impl |= Spec. We interpret this to mean that whenever intelligibility
+follows from Defn. 7 using LXP(k), intelligibility is inferred using the axioms. It means whenever
+15
+
+the LXP(k) protocol communicates Ratify, Refute or Revise tag, the antecedent of one of the axioms
+should be true8. See the table below for the mapping.
+Axiom
+If LXP(k)
+Then Axiom’s Antecedent
+Type
+Name
+action is:
+must be true:
+H → M
+Machine
+Machine sends
+Human explanation
+Confirmation
+Ratify tag
+is ratified by machine
+H → M
+Machine
+Machine sends
+Human explanation
+Refutability
+Refute tag
+is refuted by machine
+H → M
+Machine
+Machine sends
+Human explanation
+Performance
+Revise tag
+improves machine performance
+M → H
+Human
+Human sends
+Machine explanation
+Confirmation
+Ratify tag
+is ratified by human
+M → H
+Human
+Human sends
+Machine explanation
+Refutability
+Refute tag
+is refuted by human
+M → H
+Human
+Human sends
+Machine explanation
+Performance
+Revise tag
+improves human performance
+Treating interaction between human- and machine as a single session S of communication using
+LXP(k), it is evident that:
+(a) If S exhibits One-Way Intelligibility for the machine using LXP(k), then we can infer machine-
+intelligibility using the H → M axioms;
+(b) If S exhibits One-Way Intelligibility for the human using LXP(k), then we can infer human-
+intelligibility using the M → H axioms;
+(c) If S exhibits Weak Two-Way Intelligibility for human and machine, then we can infer machine-
+and human-intelligibility using the H → M and M → H axioms.
+By adopting LXP(k) as a protocol, we are immediately assuming compatibility constraints the MATCH
+and AGREE functions used by human and machine. In fact the design constraints in the table impose
+additional constraints on the antecedents of the axioms and the LEX functions MATCH and AGREE and
+the actions performed by either agent. For example: given the human and machine’s prediction
+and explanation, the human’s MATCH and AGREE functions both being true are taken as sufficient
+conditions for the machine’s explanation being ratified by human. The most interesting consequence
+results from the performance axioms. Take the Machine Performance axiom. If a Revise tag is sent
+from the machine to the human, one of MATCH or AGREE for the machine must be false before revision,
+and both MATCH and AGREE must be true after revision. For this to be sufficient for improvement
+in machine-performance means that the performance-measure used by the machine depends on the
+values of MATCH and AGREE before and after revision.
+4. Related Work
+In Appendix Appendix A we referred to a number of sources that are relevant to one or the
+other of the Intelligibility Axioms in 2.1. In this section we turn to some other relevant work. From
+8Here the mapping from the actions of the protocol to antecedents of axioms is along the intended interpretation.
+16
+
+the framework developed in this paper intelligibility can be seen as a ternary relation involving:
+the information-provider, the information provided, and the information-recipient. In the literature
+on Explainable ML, this has re-emerged as important requirement for the acceptability of ML
+(see [26] for a recent example citing earlier work [14], and [24] for an early identification of this).
+Furthermore, the explainer and the explainee can be, at different times, the same person or agent.
+A large literature has built up over recent years addressing the problems of inscrutable “black-
+box” models generated by some modern machine learning techniques which then require mechanisms
+for “explainability” [11].
+There are several excellent reviews available on Explainable Machine
+Learning (XML), and we refer to the reader to them. More broadly, the origins of XML can be
+found in a prominent DARPA project, launched in 2016 titled “Explainable Artificial Intelligence
+(XAI)” [7] which is credited with initiating efforts in XML [1]. In fact, XAI itself can be viewed as
+a continuation of pre-existing research trends: earlier approaches in machine learning largely used
+models based on knowledge representations developed in artificial intelligence that were designed
+to be interpretable (such as rules, decision trees or logical theories), whereas only recently the drive
+for accuracy on ever-larger datasets has led to models that require explanation [34].
+The DARPA project used the term “explainability” to denote the use of techniques to generate
+an explanation for a model [13]. A distinction can therefore be made between interpretable models,
+which are constrained to work in a way that is (at least, in principle) understandable to humans, and
+explainable methods, which are applied to the results obtained from black-box models [34]. This
+difference is similar to the distinction made between model transparency and post hoc explainability
+for black-box models [21]. However, interpretability is not simply a property of a class of models,
+but also of the data, feature engineering, and other factors, and, as such, it may be difficult
+to achieve in applications [21, 34].
+Explainability by post hoc methods suffers from problems
+of approximation, since the explainable model is not usually the model responsible for making
+the predictions. Recent criticism of post hoc explainability suggests such methods should not be
+adopted for certain medical [3] and legal [45] applications.
+In particular, it appears that such
+explanations may not be able to satisfy the legislative requirements for avoidance of discrimination,
+for example [45]
+In presentations of the problem of explainability it is usually assumed there is a human to which
+a machine is providing the explanation, in the terminology we have used in this paper, this means
+One-Way Intelligibility for the human. Even in this limited setting, considering only techniques for
+explanation ignores other issues, like the role of the explainee, for whom the explanation is intended,
+which is contrary to evidence from social science [26]. For instance, the diversity of explainees
+suggests thinking of explanation in terms of the understanding of the explainee [39]. From this
+standpoint [38, 39] propose that explanation should be a bi-directional process rather than a one-
+off, one-way delivery of an explanation to a recipient. Therefore explainability is a process involving
+reasoning over interpretable insights that are aligned with the explainee’s background knowledge.
+The proposal is that an explainer should allow explainees to interact and rebut explanations; in
+the proposed framework the entire explanatory process is based on a reasoning system enabling
+communication between agents.
+We are aware of at least two threads of work in the ML literature that recognises some of the
+aspects just described. In Argument-Based ML, or ABML [47, 27], data provided by a human to
+an ML engine includes explanations formulated in terms of background knowledge shared between
+human and machine. These explanations constitute ‘arguments’ for the label for data instances,
+and the ML system attempts to construct hypotheses that are consistent with the explanations.
+Learning from explanations was employed by early ML systems like MARVIN [35] that performed
+17
+
+supervised-learning in the original sense of a human guiding the construction of hypotheses by a
+machine. The learning protocol employed in such systems is naturally interactive, involving human-
+presentation of data along with explanations (if any), and revision of hypotheses by machine. The
+interaction can result in Two-Way Intelligibility if interactions consist of human refutation of a
+machine’s explanations; and the machine revises its hypothesis in response. However, no refutation
+of the human’s explanation is envisaged within ABML nor any revision of his or her hypothesis.
+A second thread of work is that on Explanatory Interactive Learning (XIL: [43, 40]). Although
+the methods proposed in [39] allow the human to interact with the machine learner, this approach is
+more fully realised in XIL, with the implementation of a revision capability based on the combination
+of active machine learning with machine-to-human explainability interaction. The ML component of
+XIL uses active learning to identify an “informative” (unlabelled) instance. This instance is labelled
+by the machine’s hypothesis, and an explanation is then generated While the specific mechanism
+for generating an explanation is not important, XIL does require the prediction and explanation to
+be characterised into one of 3 categories by a human-in-the-loop: (i) “right for the right reasons”;
+(ii) “wrong for the wrong reasons”; and (iii) “right for the wrong reasons” [33]. Nothing is done
+in categories (i) and (ii), but category (iii) initiates a revision of the machine’s hypothesis using a
+range of XAI techniques [42]9.
+In work on XIL applications to computer vision, where the learner is implemented by a deep
+network, the key intermediate step of defining “concepts” was implemented to better communicate
+with the human to enable any required revisions [40].10
+The characterisation predictions and explanations in XIL is similar in spirit to the categories
+defined by the guard functions in this paper. As with ABML, an XIL system demonstrates Two-
+Way Intelligibility when the human provides refutations (in XIL, this is done by augmenting the
+data) and the machine revises its hypothesis. Also in common with ABML, the machine does not
+provide refutations for the human’s prediction and/or explanation, and revision of the human’s
+hypothesis is not envisaged. Finally, although not cast either as ABML or XIL, but nevertheless
+related to aspects of both are implementations of incremental learning designed human-machine
+collaboration.
+Recent examples of collaboration using symbolic ML are in [32] for applications
+to computer security, and using a combination of neural and symbolic learning for collaborative
+decision-making systems for medical images [36]). Again, these approaches exhibit a form of two-
+way intelligibility, since they rely on the human providing refutations and the machine improving
+its performance as a result.
+5. Concluding Remarks
+In this paper we have sought to look beyond the current practice in Explainable Machine Learn-
+ing. It is our contention that for problems which are sufficiently complex that neither human nor
+machine have complete answers, designers of ML-based decision-support tools must be concerned
+with mutual intelligibility of information. Based on this position, we have sought to characterise
+9The category “wrong for the right reasons” does not appear to have been addressed in XIL.
+10Such concept-based explainability methods have also been applied more widely for deep learning [46].
+For
+example, concept-based explanations have recently been applied in an attempt to comprehend the chess knowledge
+obtained by AlphaZero, and concluded that this approach did reveal a number of relationships between learned
+concepts and historical game play, from standard opening moves to tactical skills, as assessed by a former world
+chess champion [23]. This is an illustration of the phenomenon predicted by Michie (see above, Thompson’s table).
+18
+
+intelligibility as a property of interaction. For the design of ML systems with humans-in-the-loop
+this means both a human and a machine need to provide explanations in a form that the other can
+inspect and evaluate critically, and respond meaningfully to that evaluation.
+But the requirement is easier to state than to achieve. There are 3 aspects to consider: (a)
+The representation used by either side for explanations; (b) How to evaluate critically; and (c) The
+rules of communicating the result of evaluation. In this paper, we have focused on (c), with the
+goal of inferring intelligibility from the messages exchanged. Nevertheless, we comment on (a) and
+(b) below, since they are relevant to LEX agents of the kind we consider in this paper.
+Aspect (a) is concerned with on how human knowledge about the world should be represented
+in order to be useful to a machine, and vice versa. McCarthy [22] envisaged this would be done as
+statements in a formal language. But this does not have to be necessarily the case. For example,
+it may be sufficient for information provided by the human to transform some or all of the inputs
+of the ML system, like the data, utility function, structure or parameters. However, we do not
+as yet have a way to do this satisfactorily for all kinds of formal languages and all kinds of ML
+systems. In the short- to medium-term therefore, we believe this will require the human decision-
+maker may have a working knowledge of the ML system, or to employ someone who does. In the
+longer term, neither of these options are practical, and decision-support tools will need mechanisms
+to receive information in natural language, and perform any manipulations to its inputs internally.
+Some progress is being made on processing information in a natural language (see for example,
+[41]), but we are still far from being able to do this well. Assuming we have the human-supplied
+information in some machine-usable form, the machine may still need to ask the decision-maker
+questions to clarify any ambiguities or inconsistencies. To resolve these would undoubtedly need
+the machine to be able to generate its own data, and ask questions about them. How should it
+represent these questions? Again, in the long-run, natural human-computer interaction techniques
+seem inevitable [6].
+The problem in (b) is concerned with the human evaluation of a machine’s explanation, and
+vice versa. Human evaluation would clearly be easier if the explanation employed concepts that
+the human can recognise. In the near-term, the machine can achieve this in one of two ways. First,
+the machine can elect to employ only those concepts that are already known to the human. The
+identification of Covid patients in the previous section is an example: the features extracted from
+chest X-rays were restricted to those identified by a radiologist. A second way is for the machine to
+show instantiations through some textual or visual means. For example, ML systems that attempted
+to discover chess concepts showed board positions exemplifying the concept. The chess-expert may
+then be able to map the machine-identified concept to some part of their chess vocabulary (such
+as “this is really about Kings in opposition”). In the long-term, as the problems, data and ML
+systems get more complex, it may not be possible to engineer an adequate set of shared concepts
+beforehand. Establishing what exactly a concept ‘invented’ by the machine really means will be a
+challenging task. The converse problem, of critical evaluation of a human explanations may prove
+more amenable. If the explanations are translatable into a formal language, then tools developed
+for model- and proof-checking can be adapted to the task. The recent promise large-scale language
+models suggests that even if explanations are in a natural language, it may be possible to develop
+language models for approximating idealised forms of logical reasoning.
+Aspect (c)–when and what to communicate–is the most amenable to analysis, given the long
+history of developing communications protocols. Surprisingly, although there is little dispute that
+explanations are intended to be communicated, little attention to paid to effective interaction
+between the agents constructing the explanations. We identify effectivity with intelligibility, and
+19
+
+show how this can be postulated as a property of a communication protocol between agents capable
+of learning to predict and explaining the predictions.
+We suggest that the design of ‘two-way
+intelligibility’ protocols should be part of the design and analysis of Explainable AI (XAI) systems
+from the ‘ground-up’. It is not coincidental that three of the R’s we have identified here — Refute,
+Revise, and Ratify — are at the heart of advancing understandability in Science. We suggest they
+may play a similar role in evolving a shared understanding of data by human-machine systems.
+Acknowledgements.
+AS is a Visiting Professor at Macquarie University, Sydney and a Visiting Professorial Fellow
+at UNSW, Sydney.
+He is also the Class of 1981 Chair Professor at BITS Pilani, Goa, the Head of the Anuradha and
+Prashant Palakurthi Centre for AI Research (APPCAIR) at BITS Pilani, and a Research Associate at TCS Research. MB
+acknowledges support in part by Rich Data Co.
+Pty and the Australian Government’s Innovations Connections scheme
+(awards ICG001855 and ICG001858). EC is supported by an NHMRC investigator grant. Many of the results reported
+here are from collaborative work done by the authors with colleagues at several institutions. We would especially like to
+acknowledge the role played by: Tirtharaj Dash, Rishabh Khincha, Soundarya Krishnan, Lovekesh Vig, Arijit Roy, Gautam
+Shroff, Paul Compton, Ross King and Stephen Muggleton. AS and MB owe a debt of gratitude to Donald Michie, who
+shaped much of their thinking on the views expressed in this paper.
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+Appendix A. Examples of Machine- and Human-Intelligibility
+Appendix A.1. Machine-Intelligibility
+Example 4 (The Machine-Confirmation Axiom). In [27], the authors suggest that a human pro-
+vides data-instances provided to the ML engine are either the usual pairs (x, yh), in which yh is the
+human’s label for the data-instance x; or triples (x, yh, eh), in which eh is human’s explanation (the
+authors use the term ‘argument’) for the label yh for x. The task of the ML engine is to construct
+a hypothesis which attempts to ensure that the prediction ym made by the hypothesis and the asso-
+ciated explanation em ar such that if yh = ym then eh and em are consistent with each other (for
+the representation used in [27] consistency-checking can be can be done efficiently using a logical
+formulation). This can be seen as a form of confirmation of the human’s prediction and explanation
+by the machine. The authors demonstrate the applicability of this form of ‘Argument-Based ML’ to
+the problems from the legal profession, and to business problems involving credit-risk.
+Example 5 (The Machine-Refutability Axiom). In [19], the authors describe a Robot Scientist.
+This is a robotic system that executes cycles of hypothesis formation, wet-lab experimentation to to
+test conjectures, execution of experiments, and refutation of hypotheses based on the results of the
+experiments. In [19], the robot scientist ‘Adam’ starts with a hypothesis about the aromatic amino-
+acid (AAA) pathway in yeast (S. cerevisiae). Adam was given a hypothesis representing existing
+23
+
+Figure A.4: A portion of the prior hypothesis about the AAA pathway in yeast provided by the biologist to the
+robot scientist Adam (from [19]).
+biological knowledge about the AAA pathway. This knowledge is a directed graph with metabolites as
+vertices in the graphs and enzymes as edges. An edge corresponds to a reaction (that is, reactions
+unidirectionally transform metabolites). A fragment of this graph is shown in Fig. A.4.
+Adam then proceeds to conduct a sequence of (self-constructed) laboratory experiments to test
+the hypothesis; and returns a new hypothesis. The new hypothesis contains additional edges that
+correctly explain observational data obtained from the experiments. In the natural sciences, the
+terms ‘hypothesis’ and ‘explanation’ are used interchangeably. In a Popper-like approach to scientific
+discovery, replacing a hypothesis with a new one entails a refutation of the older hypothesis by the
+new one. In this sense, Adam is seen as ‘refuting’ the prior explanation for the AAA pathway, and
+replacing it with a newer explanation for the data.
+Example 6 (The Machine-Performance Axiom). We show first recent results reported in [8, 9] in
+the area of drug-design. This is well-known to be a time-consuming and expensive process, requir-
+ing the involvement of significant amounts of human chemical expertise. ML-based models have
+been used to assist in this by constructing models relating chemical structure to molecular activity
+(like binding affinity, toxicity, solubility and so on), and even in the generation of entire new small
+molecules. The experiments reported consider the construction of predictive models using relations
+which are typically used to construct human-understandable explanations (like known chemical ring
+structures, functional groups, motifs and the like). The data provided were in the form of “most-
+specific explanations” for molecules using the domain-knowledge (these were constructed automat-
+ically using a technique developed in Inductive Logic Programming [28]). The machine-learning
+systems considered are two kinds of deep neural networks (a multi-layer perceptron, or MLP, and
+a graph neural network, or GNN). Figure A.5 tabulates the number of datasets on which perfor-
+mance improvements are observed, with the inclusion of human domain-knowledge. For each deep
+network type, for problems in the “Better” column, the machine uses the information provided to
+improve performance. In each such instance, the machine-performance axiom will infer that the
+domain-knowledge is intelligible to the machine, but says nothing about the remainder.
+Perhaps the earliest use of human domain-knowledge to improve the performance of a ML pro-
+gram is found in DENDRAL [20]. The DENDRAL program attempts to solve the ‘inverse’ problem
+of constructing possible structures of organic molecules that could result in data observed in a mass
+spectrogram (the mass spectrogram for uncontaminated water, for example, would show a single
+24
+
+Glyceraie-
+2-phosphate
+人
+Metabolite
+YGR254W
+YHR174W!
+YMR323W
+Phosphoenol
+pyruvate
+5-o-1-Carboxyvinyl-
+YBR249C
+YDR127W
+3-phosphoshikimate
+Arthranilate
+YDR035W
+.
+YER090
+Dino-
+YGL148W
+YKL2110
+7-phosphate
+Chorismate
+YPR060C
+YDR127W
+Shikimate-3-
+chosohate
+uinate
+Prephenate
+YDR127W
+YDR127W
+YBR166C
+YNL3160
+ikimateComparative Performance
+DNN
+(with domain-knowledge)
+Type
+Better
+Same
+Worse
+MLP
+71
+0
+2
+GNN
+63
+9
+1
+Figure A.5: The use of domain-knowledge by two kinds of deep neural networks (DNNs): mult-layer perceptrons
+(MLPs) and graph-neural networks (GNNs). Estimates of performance are obtained on 73 different datasets. Here,
+“Better” (respectively, “Same” and “Worse”) means the use of domain-knowledge results in an improvement in
+performance (respectively, no change, and worse performance).
+peak at 18, suggesting the structure H2O). The DENDRAL program employed a complete and cor-
+rect generator of molecular structures, but to identify accurate hypothesis the heuristic search used
+human knowledge that encoded chemical constraints and information on mass spectrometry.11
+Appendix A.2. Human-Intelligibility
+Example 7 (The Human-Confirmation Axiom). The tabulation of the radiologist’s assessment of
+machine explanations generated for Covid in Fig. 1 shows there are 17 instances where the radiologist
+thinks the explanation is sufficient. In all such cases, the human-confirmation axiom would infer
+that the corresponding explanations were intelligible to the radiologist.
+In the example described earlier on the Robot Scientist, the prior hypothesis provided for the
+AAA pathway was in fact known in advance to be incorrect. Substantially more additions to the
+existing knowledge about yeast by Adam was reported in [18], in which Adam identified the functions
+of several novel hypotheses concerning the identity of genes encoding enzymes in metabolic pathways
+in yeast. These hypotheses were later confirmed by gold-standard experiments constructed by human
+scientists in the laboratory, making it possibly the first-of-a-kind result of scientific discovery by a
+ML engine accompanied by confirmation by human specialists.
+Example 8 (The Human-Performance Axiom). Michie’s “Ultra-Strong” criterion for machine
+learning stipulates that a machine must be able not only to output its hypotheses in symbolic form
+but also enable humans, given some study time, to subsequently apply them and thereby improve
+their performance [24]. In [30] for the first time a set of operational definitions of the Ultra-Strong
+criterion were developed, based on the use of an Inductive Logic Programming (ILP) to learn sym-
+bolic hypotheses in the form of logic programs. Since pure logic programs can be read as declarative
+concept definitions they are, at least in principle, humanly-understandable. Comprehensibility was
+defined as a predicate with two arguments, a definition or logic program P and a sample of human
+subjects S. Comprehensibility of P is then quantifiable in terms of the mean accuracy of human
+subjects from S on prediction tasks containing unseen data from the same problem domain as the
+training data However, several additional operational definitions were introduced to characterise
+comprehensibility, for example, the textual complexity of concept definitions, and time taken for
+humans to study training data and concept definitions.
+Empirical evaluation of human performance was in terms of predictive accuracy on a problem
+based on the recursive definition of an ancestor in a family tree. However, to control for effects
+11DENDRAL is also an early example of building an ‘expert system’ using machine learning. Contrary to a popular
+(mis)conception, there is a long history of constructing such systems by machines, with assistance from humans.
+25
+
+due to prior background knowledge, this was presented to the human participants as a problem in a
+fictitious domain concerning statements about exothermic chemical reactions. Human participants
+were split into two groups. The first group was tested on their ability to correctly classify examples
+from the chemistry domain after being exposed to the training data alone.
+However the second
+group was provided, in addition to the training data, with rules learned by the ML, and then their
+predictive ability was tested in the same way. For the ML to satisfy the Ultra-Strong criterion, the
+performance of the first group should be significantly lower than that of the second group, which was
+the result reported in [30].
+Appendix B. Automaton Transitions in a Session
+We assume a session Smn in which the automaton an receives a message µ from am; executes code
+Π = (D′
+n := Dn ∪ {(x, ym, em, m)} ∧ P ∧ yn := PREDICT(x, Hn) ∧ en := EXPLAIN((x, yn), Hn) ∧
+y′
+n := PREDICT(x, H′
+n)
+∧
+e′
+n := EXPLAIN((x, y′
+n), H′
+n); checks guard g; and sends message µ′.
+The transition system can be represented as a set of 4-tuples (γ, Π, g, γ′).
+Here γ and γ′ are
+(global) configurations. We tabulate below the set of transitions when an sends a message to am
+(the transitions for am can be obtained by interchanging an and am). The global configurations
+are γ = ((Hm, Dm), +(n, µ), (Hn, Dn), −(m, µ)) and γ′ = ((Hm, Dm), −(n, µ′), (H′
+n, D′
+n), +(m, µ′)).
+Below we tabulate only µ, P, g, and µ′. LEARN(Hn, ·, ·) returns Hn if no suitable generalisation is
+found. In the tabulation below, if H′
+n = Hn then y′
+n = yn and e′
+n = en. In the tabulation, g′ =
+MATCHn(y′
+n, ym) ∧ AGREEn(e′
+n, em).
+26
+
+Trans
+µ (received by an)
+P
+g
+µ′ (sent by an)
+0.
+No message
+H′
+n := Hn
+⊤
+(Init, (x, y′
+n, e′
+n))
+1.
+(Init, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+2.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+3.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+4.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+5.
+(Init, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+6.
+(Init, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+7.
+(Ratify, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+8.
+(Ratify, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+9.
+(Ratify, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+10.
+(Ratify, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+11.
+(Ratify, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+12.
+(Ratify, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+13.
+(Refute, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+14.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+15.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+16.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+17.
+(Refute, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+18.
+(Refute, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+19.
+(Revise, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+20.
+(Revise, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+21.
+(Revise, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+22.
+(Revise, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+23.
+(Revise, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+24.
+(Revise, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+25.
+(Reject, (x, ym, em))
+H′
+n := Hn
+g1
+(Ratify, ((x, y′
+n, e′
+n))
+26.
+(Reject, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+27.
+(Reject, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g2 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+28.
+(Reject, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ ¬g′
+(Refute, ((x, y′
+n, e′
+n))
+29.
+(Reject, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+g3 ∧ g′
+(Revise, ((x, y′
+n, e′
+n))
+30.
+(Reject, (x, ym, em))
+H′
+n := Hn
+g4
+(Reject, ((x, y′
+n, e′
+n))
+31.
+(Ratify, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+32.
+(Refute, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+33.
+(Revise, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+34.
+(Reject, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+35.
+(Init, (x, ym, em))
+H′
+n := Hn
+⊤
+(Term, (x, y′
+n, e′
+n))
+36.
+(Term, (x, ym, em))
+H′
+n := LEARN(Hn, D′
+n)
+em = ▲
+No message
+37.
+(Term, (x, ym, em))
+H′
+n := Hn
+em ̸= ▲
+No message
+Proposition 2. Let ψ be an execution of the LXP protocol in a session between compatible agents
+am and an.
+• The transitions correspond to rows 8,9,10,11 and 12 will not occur in ψ.
+• The transitions correspond to rows 20,21,22,23 and 24 will not occur in ψ.
+• The transitions correspond to rows 25,26,27,28 and 29 will not occur in ψ.
+Proof. We assume each of the above transitions represents a communication of the message µ′ =
+(t′, x, y′
+n, e′
+n)). Without loss of generality, we assume that n is the sender and m is the receiver
+27
+
+of this communication. We observe that the message tag in the above communication is different
+from Init. So it is immediately preceded by other transitions. These preceding transitions would
+represent communications in which the agent m sends the message µ = (t, (x, ym, en)) and the
+agent n receives it. Let Hm and Hn be the hypotheses of m and n before communicating the
+message µ, H′
+m and H′
+n be the hypotheses of m and n after communicating µ′. H′
+n be the updated
+hypothesis of n after receiving the message m. Also observe that ym := PREDICT(x, Hm), em :=
+EXPLAIN((x, ym), Hm), y′
+n := PREDICT(x, H′
+n) and e′
+n := EXPLAIN((x, y′
+n), H′
+n).
+Hm, ym, em
+Hn, yn, en
+Hm, ym, em
+H′
+n, y′
+n, e′
+n
+H′
+m, y′
+m, e′
+m
+H′
+n, y′
+n, e′
+n
+m sends µ
+n receives µ
+n sends µ′
+m receives µ′
+n checks the guards using
+MATCHn(yn, ym), AGREEn(en, em)
+MATCHn(y′
+n, ym), AGREEn(e′
+n, em)
+m checks the guards using
+MATCHm(ym, y′
+n), AGREEm(em, e′
+n)
+MATCHm(y′
+m, y′
+n), AGREEm(e′
+m, e′
+n)
+• Now let us consider the transitions 8,9,10,11 and 12. It is clear that the message tag t in each
+of these transitions is Ratify. It means the previous transition should be any one of 1,7,13,19
+and 25. Also there is no change in the hypothesis of the agent m and the previous transition’s
+guard MATCHn(yn, ym)∧AGREEn(en, em) is true. Since this is a collaborative session, the guard
+MATCHm(ym, yn) ∧ AGREEm(em, en) is also true. Hence the guards for 8,9,10,11 and 12 are all
+false and these transitions will never occur in any collaborative session using the LXP protocol.
+• Now let us consider the transitions 20,21,22,23 and 24. It is clear that the message tag t in
+each of these transitions is Revise. It means the previous transition should be any one of
+3,5,9,11,15,17,21,23,27 and 29. In all theses transitions, the guard g′ (which is MATCHn(y′
+n, ym)∧
+AGREEn(e′
+n, em) is true.
+Since this is a collaborative session, the guard MATCHm(ym, y′
+n) ∧
+AGREEm(em, e′
+n) is also true. Hence the guards for 20,21,22,23 and 24 are all false and these
+transitions will never occur in any collaborative session using the LXP protocol.
+• Now let us consider the transitions 25,26,27,28 and 29. It is clear that the message tag t in
+each of these transitions is Reject. It means the previous transition should be any one of
+6,12,18,24 and 30. Also there is no change in the hypothesis of the agent m and the previous
+transition’s guard ¬MATCHn(yn, ym) ∧ ¬AGREEn(en, em) is true. Since this is a collaborative
+session, the guard ¬MATCHm(ym, yn) ∧ ¬AGREEm(em, en) is also true. Hence the guards for
+25,26,27,28 and 29 are all false and these transitions will never occur in any collaborative
+session using the LXP protocol.
+Remark 3. Let Smn be a collaborative session between agents am and an consisting of a sequence
+of configurations ⟨γ1, γ2, . . . , γk⟩, where γi = (γm,i, γn,i). Let γm,i = (·, ·, µm,i), γn,i = (·, ·, µn,i)
+where µm,1 = +(n, (Init, ·)) and µ·,k = +(·, (Term, ·)).
+• If there is an i such that the message tag in µm,i or µn,i is Ratify, then for each j such that
+i < j < k, rj = rj−1.
+28
+
+• If there is an i such that the message tag in µm,i or µn,i is Reject, then for each j such that
+i < j < k, rj = rj−1.
+29
+
diff --git a/a9AzT4oBgHgl3EQf2v6K/content/tmp_files/load_file.txt b/a9AzT4oBgHgl3EQf2v6K/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..ab6ded46afbf9119578079fa7064f338f2c3a90b
--- /dev/null
+++ b/a9AzT4oBgHgl3EQf2v6K/content/tmp_files/load_file.txt
@@ -0,0 +1,1143 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf,len=1142
+page_content='A Protocol for Intelligible Interaction Between Agents That  Learn and Explain  Ashwin Srinivasana,∗, Michael Bainb, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Baskarc, Enrico Coierad  aDept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' of CSIS& APPCAIR, BITS Pilani, Goa, India  bSchool of CSE, University of NSW, Sydney, Australia  cDept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' of CSIS, BITS Pilani, Goa, India  dCentre for Health Informatics, Macquarie University, Sydney, Australia  Abstract  Recent engineering developments have seen the emergence of Machine Learning (ML) as a powerful  form of data analysis with widespread applicability beyond its historical roots in the design of  autonomous agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, relatively little attention has been paid to the interaction between  people and ML systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Recent developments on Explainable ML address this by providing visual  and textual information on how the ML system arrived at a conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In this paper we view the  interaction between humans and ML systems within the broader context of interaction between  agents capable of learning and explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Within this setting, we argue that it is more helpful to  view the interaction as characterised by two-way intelligibility of information rather than once-off  explanation of a prediction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We formulate two-way intelligibility as a property of a communication  protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Development of the protocol is motivated by a set of ‘Intelligibility Axioms’ for decision-  support systems that use ML with a human-in-the-loop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The axioms are intended as sufficient  criteria to claim that: (a) information provided by a human is intelligible to an ML system;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (b)  information provided by an ML system is intelligible to a human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The axioms inform the design  of a general synchronous interaction model between agents capable of learning and explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We identify conditions of compatibility between agents that result in bounded communication, and  define Weak and Strong Two-Way Intelligibility between agents as properties of the communication  protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Keywords:  Learning Agents, Two-Way Intelligibility, Communication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  ∗Corresponding author  Preprint submitted to Elsevier  January 6, 2023  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='01819v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='AI]  4 Jan 2023  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Introduction  In the second half of his seminal 1950 paper [44], Alan Turing describes an autonomous agent  that has the capacity to alter its programming based on experiments and mistakes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Since then,  developments in mathematics and computing have made steady progress and one form of ML – deep  neural networks – has been able to achieve startlingly good predictive performance when provided  with sufficient data and computational resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  A difficulty has arisen when the models ML methods construct have to be examined by humans.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  For example, a deep neural network may predict, with high accuracy, the occurrence of malignancies  from X-ray images.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If an explanation of how that prediction was arrived at is required by the  clinician, then we hit an “intelligibility bottleneck”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Some of this arises from a mismatch between  what certain ML practitioners view as suitable explanations, and what subject end-users require [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  If current techniques for explanation are unfit for purpose, they relegate ML systems to the status  of drugs for which no definitive biological mechanism is understood, but which nonetheless may be  effective [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Whilst this may allow ML to be applied for some tasks, it falls short of “human-level”  performance as far as explainability goes [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1  But what does it mean for an explanation from an ML-system to be understandable to the  clinician, or, more broadly, to a person interacting with a ML- based system?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' One could view this  as a requirement for humans and ML systems to maximise their mutual knowledge, developed over  sequences of communicative interactions [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' At least some shared understanding of the concepts  and terminology in a domain appears to be needed for communication between human and machine,  just as between humans.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Serious consequences may follow when this is lacking, for example, in the  misinterpretation of scientific knowledge in legal proceedings [16, 37], or when the rate of production  and complexity of data outpaces the abilities of specialists to assimilate and process them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  In such settings, we would expect human-machine systems to become increasingly collaborative,  with neither human nor machine having complete answers to problems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We expect not only that  information provided by a machine should be intelligible to a human, but also that any information  provided by a human will need to be intelligible to the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In this paper, we view this ‘two-way  intelligibility’ requirement within the broader context of two-way intelligible interaction between  agents capable of learning and explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The main contributions of the paper are as follows:  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We propose the notion of Two-Way Intelligibility between agents as a pre-requisite in the  design of Explainable Artificial Intelligence (XAI) systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We characterise Two-Way In-  telligibility as the consequence of the interaction between a pair of communicating agents  capable of learning and explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This includes, but is not limited to, a human and an AI  system, and provide a set of intuitive axioms to specify the special case of human-machine  intelligibility;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A detailed description of a communication protocol between agents, such that both One-Way  and Two-Way Intelligibility can be defined as properties arising from the execution of the  1We  recognise  that  there  are  clinical  settings  where  explanations  may  not  be  required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  ARDA,  for  example,  is  a  highly  accurate  ML-based  tool  for  diagnosis  of  diabetic  retinopathy  (see:  https://health.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='google/caregivers/arda/).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  based on the work reported in [12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  It has been trained using  labelled data provided by over 100 clinicians, and has been tested in a clinical trial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is a device for triage-assistance  in settings where a clinician examines 1000s of patients a day, and the tool is considered adequately field-tested.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In  this paper we are concerned instead with what needs to be done if explanations are needed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2  protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We define condition of compatibility between agents under which the communication  is bounded;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and conditions under which the protocol can be seen as a correct implementation  of the intelligibilty axioms proposed for human-machine interaction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The strange case of Thompson’s table  An early description of the understandability of a machine’s explanation to a human spe-  cialist is provided by Michie [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The description begins with the construction of a black  box for a chess endgame (the interjections in brackets are ours):  At the meeting in Toronto in 1977 of the International Federation for Informa-  tion Processing, Kenneth Thompson of Bell Telephone Laboratories presented a  computer program for playing the chess end-game of King and Queen against  King and Rook.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' He had done this by the ultimate in ‘hammer and tongs’ meth-  ods: in the absence of a complete set of rules for playing the end-game, he had  previously programmed the machine to work out what to do in every single  possible position .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' All these moves were then loaded into a gigantic ‘look-up’  table in the machine’s memory .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Thompson invited [International Masters] to  demonstrate winning play for the Queen’s side against the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' To their  embarrassment they found they could not win, even after many attempts .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The  machine repeatedly conducted the defence in ways which to them were so bizarre  and counter-intuitive [like separating King and Rook] that [the Chess Masters]  were left grasping air .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Naturally [they] found the experience upsetting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' They  wanted to ask the program to explain its strategy, but this of course neither it  nor its author could do.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The answer in every case was, ‘It’s in the table.’ (pg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  64, [25])  Michie describes how this situation is not very different to the case of ML programs that are  unable to explain their decision-making.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' He sees this as not being especially problematic  in some circumstancesa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However in some other cases, involving decision-making in critical  areas, he notes that lack of meaningful feedback from the machine can become a serious  issue:  But what if the system were doing something of social importance, such as man-  aging a complex control function in factory automation, transport or defence?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Two supervisors, let us imagine, are responsible for intervening manually in the  event of malfunction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The system now does the equivalent in industrial or mili-  tary terms of ‘separating its King and Rook’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ‘Is this a system malfunction?’' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' the  supervisors ask each other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' They turn to the system for enlightenment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' But it  simply returns the same answer over and over again .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Any socially responsible  design for a system must make sure that its decisions are not only scrutable but  refutable .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' (“The lunatic black box”, pg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 68, [25]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  aSurprisingly, Michie includes the possibility that scientific discovery may even benefit from highly pre-  dictive but opaque machine-constructed models, since it would force scientists to develop new explanations  for unexpected predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  3  X-ray Not Covid because:  The explanation does not mention  Air-space opacification probability is low, and  the right upper lobe air space  Cardiomegaly probability is high;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and  opacification consistent with Covid  Emphysema probability is low  Pneumothorax probability is low  Fibrosis probability is low  Machine’s explanation  Radiologist’s feedback  Radiologist’s Opinion about the Model’s  Explanation  Prediction  Correct  Wrong  Unsure  Sufficient  17  0  0  Incomplete  1  3  1  Incorrect  3  2  3  Figure 1: Top: The machine’s explanation and a senior radiologist’s feedback;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and Bottom: A tabulation of the  radiologist’s assessment of explanations from the ML-based system on a set of test images.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A Model for Intelligible Interaction  We motivate the development of a general interaction model between agents that learn and  explain by looking first at possible criteria for inferring One-Way Intelligibility of human-machine  interaction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' These criteria will then inform the design of a communication protocol for intelligible  interaction in the more general setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Specifying Intelligibility in Human-Machine Interaction  We motivate the notion of intelligible interaction using a recent research study on identification of  Covid-19 patients, based on X-ray images.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The automated tool described in [17] uses a hierarchical  design in which clinically relevant features are extracted from X-ray images using state-of-the-  art deep neural networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Deep neural networks are used to extract features like ground-glass  opacity from the X-rays;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and the system also includes a network for a deep network for prediction  of possible disease (like pneumonia).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The output from the deep networks are used by a symbolic  decision-tree learner to arrive at a prediction about Covid-19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Explanations are textual descriptions  obtained from the path followed by the decision-tree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Results reported in [17] describe how this  neural-symbolic approach compares to an end-to-end monolithic neural approach (the predictive  results of the two are comparable).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  However, our interest here is on the clinical assessment of  the explanations produced by the symbolic model by radiologists: Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 1 shows an example of a  machine’s explanation and a clinician’s assessment of that explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A tabulation of assessment  on several “test” images is also shown.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' From the tabulation we can see: (a) The radiologist does  not always think the model is correct (this is despite a supposed predictive accuracy of over 99%  claimed for the model);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' (b) The radiologist is more likely to refute the explanation when he thinks  the model is wrong;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' (c) Overall, the radiologist refutes the explanations in 13/30 ≈ 43% of the  instances and finds the explanations acceptable for the remaining 17 cases (≈ 57%).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We would like to say that the machine’s explanations are ‘intelligible’ to the human, since they  are all either confirmed or refuted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We propose to capture this notion of intelligibility using the  following six axioms that are concerned with communication of information in two categories:2  2We restrict information to be in the form of prediction accompanied by an explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For simplicity, we refer  4  Human-to-Machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Axioms in this category are concerned with machine-intelligibility of the  information provided by a human to the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Machine-Confirmation: If the machine ratifies a human-explanation then the human’s  explanation is intelligible to the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Machine-Refutability: If the machine refutes a human-explanation then the human’s  explanation is intelligible to the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Machine-Performance: If the human-explanation improves machine-performance then  the human’s explanation is intelligible to the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Machine-to-Human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This concerns the human-intelligibility of explanations provided by a ma-  chine:  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human-Confirmation: If the human ratifies a machine-explanation then the machine’s  explanation is intelligible to the human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human-Refutability: If the human refutes a machine-explanation then the machine’s  explanation is intelligible to the human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human-Performance: If the machine-explanation improves the human’s performance  then the machine’s explanation is intelligible to the human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  For the instances in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 1, one or the other of the Human-Confirmation axiom or the Human-  Refutability axiom will hold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Appendix Appendix A contains more examples from the ML literature  where conditions of the axioms can be said to hold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' At this point, the following clarifications may  be helpful:  The examples in Appendix Appendix A are by no means the only ones in the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' How-  ever, some of the conditions have received less attention than the others (machine-refutability,  and human-performance are examples);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The axioms are not intended to be a complete definition of machine- or human-intelligibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Thus it is possible, for example, that none of the conditions for the machine-to-human axioms  hold, and the machine’s explanation may still be human-intelligible;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The axioms also do not  specify what, if anything, should be done if one of more of them hold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For example, if a  machine’s explanation is refuted, then what should the machine do about it?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Two aspects of the axioms might escape attention are: (a) Although individually, the axioms  result in an inference of One-Way Intelligibility, but taken together they allow an inference  of Two-Way Intelligibility;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (b) The inference of intelligibility will depend on the specific  human and machine involved in the interaction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Thus, the axioms can at best be seen as a partial specification for intelligibility within the  context of an interaction model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the next section, we develop a general model of interaction  between agents that use agent-specific functions for learning and explanations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We then use this  model to identify conditions of collaborative communication between human and machine;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and  identify two-way intelligibility based on the messages exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We will return in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='3 to the  notion of the axioms as a specification for intelligibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  to both as an explanation in the axioms: we disentangle these later in the paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The constituents of explanations  are left open: the axioms identify conditions when these constituents are intelligible to the recipient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Interaction between LEX Agents  We now develop an interaction model for the more general setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let A be a set of agents that  have capabilities for learning (induction) and explanation (justification).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='3 We will call such agents  LEX agents (short for Learn-and-Explain).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Specifically, we assume that the interaction between  LEX agents will be modelled by communicating finite-state automata which we will also call LEX  automata.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We will assume each LEX automaton am for the agent m has access to: a hypothesis  Hm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and a dataset Dm consisting of 4-tuples {(xi, yi, ei, pi)}N  i=1, where xi is a data-instance, yi is a  label for xi;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ei is an explanation for yi given xi;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and pi represents the provenance for the label and  explanation (that is, details about the origin of yi, ei for an xi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Additionally, we will assume each  LEX automaton am also has access to the following automaton-specific functions:  (a) PREDICTm that returns the prediction of a data-instance x using its hypothesis;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (b) EXPLAINm that returns an explanation for a data-instance x using its hypothesis;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (c) LEARNm that learns a possibly new hypothesis given its existing hypothesis, dataset, and a  possibly new data-triple;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (d) MATCHm which is true if a pair of predictions y, y′ match;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and  (e) AGREEm that is true if a pair of explanations e, e′ agree with each other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We call these LEX-functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the rest of the paper, it will be understood that these functions are  automaton-specific and we will drop the subscript on the functions unless we want to emphasise  them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We will return to these functions later in the paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Additionally we will assume a special  agent ∆ ̸∈ A, called the oracle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ∆ is a non-LEX agent, but it will be convenient to model it’s  interaction with other LEX automata using the same communication protocol used for LEX automata.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' LXP: A Communication Protocol for LEX Automata  We will adopt a protocol in which messages are exchanged between a pair of LEX automata  am, an ∈ A in a session.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='4 In this paper, we will only be focusing on communication that takes  place one-instance-at-a-time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The messages in the communication protocol follows the grammar-like  rules shown below:  SendMessage ::= Send(M,(T,(X,Y,E)))  ReceiveMessage ::= Receive(M,(T,(X,Y,E)))  Send ::= ’+’  Receive ::= ’-’  M ::= m, m ∈ A ∪ {∆}  T ::= t, t ∈ {Init, Ratify, Refute, Revise, Reject, Term}  X ::= x, x ∈ X  Y ::= y, y ∈ Y ∪ {′?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='′}  E ::= e, e ∈ E ∪ {′?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='′, ▲}  Here ϵ denotes a empty string (‘do nothing’);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' X is a set of data-instances;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Y is a set of ‘labels’ for  data-instances, and ’?’' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' is to be read as “not known”;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' E is a set of explanations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The explanation  ▲ is to be read as ‘oracular statement”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  3The capacity for inference (deduction) is taken for granted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  4We will use the terms “agents” and “automata” interchangeably.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  6  Figure 2(a) shows the messages sent and received by an automaton for an agent (other than ∆),  and Fig 2(b) shows the corresponding messages sent and received by ∆.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Informally, the figure tells  us that every session between a pair of LEX automata has to explicitly initiated and terminated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The session can be terminated by either automaton, and an automaton can only initiate a new  session after terminating an existing session.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We will also require that only messages sent by ∆ can contain ▲ as an explanation and that  the following restriction holds on the LEX functions: for any agent m ̸= ∆ and Dm, if Hm =  LEARNm(·, Dm) and (x, y, ▲) ∈ Dm, then AGREEm(PREDICTm(x, Hm), y) = TRUE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Informally, this  assumes the predictions by the oracle are always correct, and therefore all non-oracular agents have  to ensure their predictions are consistent with the predictions they have received from the oracle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  To specify the LXP protocol fully we need to define the transition system, which we describe next.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Guarded Transitions  Let Smn(x) denote a session between am and an in A ∪ {∆} about a data-instance x ∈ X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Correctly there may be multiple sessions between am,n involving the same data-instance, and we  would need an additional index to capture this.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We ignore this here, and will usually omit x, when  the context is obvious.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We also adopt the convention that the session Smn is initiated by am.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Smn can be represented by the execution of the protocol which results in a sequence of ‘configura-  tions’ ⟨γmn,1, γmn,2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' , γmn,k⟩.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is helpful to think of any configuration γmn,i as being composed of  a pair of ‘local configurations’ of the automaton γm,i for am and γn,i for an, and γmn,i = (γm,i, γn,i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We will define γm,i = (sm,i, (Hm,i, Dm,i), µm,i) and γn,i = (sn,i, (Hn,i, Dn,i), µn,i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Here the s·,i are  states;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' H·,i are hypotheses;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' D·,i are 4-tuples;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' µ·,i is the message sent or received.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' From the gram-  mar rules, messages are of the form +(A, (t, (x, y, e))) or −(A, (t, (x, y, e)), where A is either m or  n (denoting am or an for short);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' t is a message-tag, x is a data-instance, y is a label, and e is an  explanation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The corresponding local configuration γn,i is similar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Before defining transitions between configurations, we introduce the guards here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The guard ⊤  is trivially true in all configurations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The definitions of non-trivial guards are the same for all LEX  agents, and we define them here for the receiving automaton (an).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 1 (Guards).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let an be a LEX agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Let γmn,i = (γm,i, γn,i) be a configuration in  a session Smn, where γm,i = (sm,i, (Hm,i, Dm,i), µm,i) and γn,i = (sn,i, (Hn,i, Dn,i), µn,i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Let  µm,i = +(n, (tm, (x, ym, em))), µn,i = −(m, (tm, (x, ym, em))), yn = PREDICTn(x, Hn,i), and en =  EXPLAINn((x, yn), Hn,i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then we define the guards:  g1: MATCHn(yn, ym) ∧ AGREEn(en, em)  g2: MATCHn(yn, ym) ∧ ¬AGREEn(en, em)  g3: ¬MATCHn(yn, ym) ∧ AGREEn(en, em)  g4: ¬MATCHn(yn, ym) ∧ ¬AGREEn(en, em)  Remark 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We note the following:  (a) It is not hard to see that at most one of the four guards can be true in a configuration γmn,i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (b) The guards only apply to the automaton in the CAN SEND state in γmn,i (here an);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  7  START  CAN RECEIVE  CAN SEND  END  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' +(A, (Init, (X1, Y1, E1))  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' −(A, (Init, (X2, Y2, E2)))  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' −(A, (T, (X2, Y2, E2)))  REV;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' +(A, (Revise, (X2, Y2, E′  2)))  REJ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' +(A, (Reject, (X2, Y ′  2, E′  2)))  RAT;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' +(A, (Ratify, (X2, Y ′  2, E′  2)))  REF;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' +(A, (Refute, (X2, Y2, E′  2)))  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ±(A, (Term, (X3, Y3, E3)))  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ±(A, (Term, (X2, Y2, E2)))  START  END  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' −(A, (Init, (X1, ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=', ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=')))  ⊤;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' +(A, (Term, (X1, Y1, ▲)))  (a)  (b)  Figure 2: Messages sent (’+”) and received (’-’) by: (a) automata for agents other than the oracle;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (b) the oracle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Here ⊤ stands for a guard condition that is trivially true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' RAT, REF, REV and REJ represent the guard conditions  used by the guarded transition system, which are described below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  8  (c) The guards for all automata use only the LEX functions MATCH and AGREE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, since  these functions are automaton-specific, the value of the guard function in one automaton may  or may not agree with the corresponding value in a different automaton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We will restrict  ourselves to the compatible automata, which we define below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The guards are used to define guarded transition relations (or simply transition relations).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In-  tuitively, transitions can be understood as follows: if a guard g is TRUE in a configuration after  performing some computation then an action is executed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The action consists of receiving a message  or sending a response (except when the received tag is Term).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 2 (Guarded Transition Relation).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A guarded transition relation is a set of 4-tuples  ((γm, γn), Π, g, (γ′  m, γ′  n)), where γm, γn, γ′  m and γ′  n are (local) configurations;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Π is the computations  performed by the sending automaton5 to evaluate g and update (γm, γn) to (γ′  m, γ′  n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' g is a Boolean  guard function defined over local configurations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  To address (c) in Remark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 1, we focus on the special case where a pair of LEX agents that agree  with each other on their MATCH and AGREE functions within a session.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 3 (Compatible Automata).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Smn be a session between LEX agents am and an.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let  Ym = {ym : +(n, (·, (x, ym, ·))} be the set of predictions in messages sent by am to an and Yn = {yn :  +(m, (·, (x, yn, ·))} be the set of messages sent by an to am.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Em = {em : +(n, (·, (x, ·, em))}  be the set of explanations in messages sent by am to an and En = {en : +(m, (·, (x, ·, en)))} be  the set of explanations in messages sent by an to am.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We will say there is a functional agreement  on predictions between am and an in Smn, or am  ≃y an in Smn, if for all ym ∈ Ym and yn ∈  Yn, MATCHm(ym, yn) = MATCHn(yn, ym).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Similarly we will say there is a functional agreement on  explanations between am and an in Smn, or am ≃e an in Smn, if for all em ∈ Em and en ∈ En  AGREEm(em, en) = AGREEn(en, em).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We will say automata am and an are compatible in session Smn  iff am ≃y an and am ≃e an in Smn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We assume that the oracle ∆ is compatible with any LEX agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  A session involving compatible agents will be called a collaborative session.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We now examine  transitions between automata am and an in a collaborative session.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Assume automaton an receives a  message µ from am.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then, an executes code Π;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' checks the guard g;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' updates the current configuration  γ to a new configuration γ′;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and sends a message µ′ to m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For a pair of agents am and an, neither  of which is ∆, the transitions specify that the message sent by an to am satisfies the following  constraints:  Explanation  AGREE(en, em)  ¬AGREE(en, em)  MATCH(yn, ym)  Ratify  Refute or  Prediction  (A)  Revise (B)  ¬MATCH(yn, ym)  Refute or  Reject  Revise (C)  (D)  Note that in category (A), guard g1 will be true;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' in category (B), guard g2 will be true;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' in  category (C), guard g3 will be true;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and in category (D), guard g4 will be true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In addition, a  further test (g′) will be used in (B) and (C) to decide on whether a Refute or Revise message-tag  5The automaton which is in CAN SEND in γm or γn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  9  is sent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Appendix Appendix B lists all possible transitions involving non-trivial guard functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Restricting am and an to being compatible automata eliminates some elements from the set of  transitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 4 (Transitions in a Collaborative Session).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Smn be a session between compati-  ble agents am and an.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The transitions for Smn can be specified as a set of 4-tuples (γ, Π, g, γ′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Let γ = ((sm, (Hm, Dm), +(n, µ)), (sn, (Hn, Dn), −(m, µ))) and γ′ = (s′  m, ((Hm, Dm), −(n, µ′)),  (s′  n, (H′  n, D′  n), +(m, µ′))), where sm = CAN RECEIVE, sn = CAN SEND;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' s′  m = CAN SEND, s′  n =  CAN RECEIVE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Let Π = (D′  n := Dn ∪ {(x, ym, em, m)) ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' P ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' yn := PREDICT(x, Hn) ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  en :=  EXPLAIN((x, yn), Hn) ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' y′  n := PREDICT(x, H′  n) ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' e′  n := EXPLAIN((x, y′  n), H′  n)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let g′ = MATCH(y′  n, ym)  ∧ AGREE(e′  n, em).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Using Proposition 2 in Appendix Appendix B, the legal transitions for an are specified below (for  simplicity, we only show µ, P, g and µ′;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' the numbering of transitions is from the complete tabulation  in Appendix Appendix B).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Trans  µ (received by an)  P  g  µ′ (sent by an)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  No message  H′  n := Hn  ⊤  (Init, (x, y′  n, e′  n))  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  15.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Term, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  em = ▲  No message  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Term, (x, ym, em))  H′  n := Hn  em ̸= ▲  No message  The legal transitions for am can be obtained by interchanging n and m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  In Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 4, we assume that Revise is sent by an only if its LEARN function can find a hypothesis  H′  n such that the resulting prediction y′  n matches ym, and the resulting explanation e′  n agrees with  em (that is, g′ is true).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Example 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let am and an be compatible automata.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Suppose am initiates the transition by sending  the message +(n, (Init, (x, ym, em))) to an.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Suppose g2 ∧ ¬g′ is true for an.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then automaton an  responds (using transtion 2) with −(m, (Refute, (x, y′  n, e′  n))).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Suppose g3∧g′ is true for am.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' That is,  10  automaton can revise its hypothesis to ensure that its prediction y′  m matches y′  n and its explanation  e′  m agrees with e′  n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then an and sends the message +(n, (Revise, (x, y′  m, e′  m))) (using transition  17).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Since g1 is now necessarily true, an sends +(m, (Ratify, (x, y′, e′))) (using transition 19).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' am  then terminates the session (using transition 31).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We can construct an abstraction of the set of transitions in the form of a ‘message-graph’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This is  in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 3: for simplicity, to the row numbers in the tabulation in Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='6 It is evident from the  self-loops in the graph that communication can become unbounded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' To redress this, we alter the  LXP protocol by replacing transitions encoding self-loops.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 5 (Transitions in a Modified Protocol).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' From Remark 3 in Appendix Appendix  B,  the entries for 7 and 30 can be replaced with transitions 7′ and 30′ below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In addition, we rename  transition 14 and 16 as 14 − k and 16 − k to denote that at most k occurrences of the transition can  occur on any execution;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and add the transitions 14′ and 16′ to allow termination after k iterations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The modified set of transitions are shown below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  µ  P  g  µ′  7′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := Hn  g1  (T erm, (x, y′  n, e′  n))  14′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n :=:= LEARN(Hn, D′  n)  g2 ∧ ¬g′  (T erm, (x, y′  n, e′  n))  14-k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n :=:= LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, (x, y′  n, e′  n))  16′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n :=:= LEARN(Hn, D′  n)  g3 ∧ ¬g′  (T erm, (x, yn, en))  16-k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n :=:= LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, (x, y′  n, e′  n))  30′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := Hn  g4  (T erm, (x, y′  n, e′  n))  We will call the modified protocol LXP(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The corresponding message-graph is in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 3(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Protocol Properties  It is straightforward to show that communication between compatible agents using LXP(k) is  bounded:  Proposition 1 (BoundedCommunication).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Fig 3(c) represents the message graph of a col-  laborative session using the LXP(k) protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then any communication in the session has bounded  length.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' All messages in a session commence with Init and end with Term message-tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The result  follows straightforwardly from the fact that fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 3(c) is a DAG except the loops 14-k and 16-k at  Refute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' But each of these loops can occur at most k times.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Therefore any path between Init and  Term is bounded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We note that without the restriction to compatible agents, it is not possible to guarantee bounded  communication (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 3(a), which contains several cycles).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' One- and Two-Way Intelligibility can be  stated as properties of LXP(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 6 (Messages sent in a Session Smn).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Smn be a session between agents m and  n consisting of a sequence of configurations ⟨γ1, γ2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' , γk⟩, where γi = (γm,i, γn,i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let γm,i =  6Informally, for an edge (v1, v2) in the graph, the label for v1 is the message-tag received, and the label for v2  is the message-tag sent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The edges are labelled with the corresponding transition entries in the table in Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Correctly, the edge-label should be distinguish between which of an or am is sending, and which is receiving along  with the message content.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This level of detail is not needed for what follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  11  Init  Ratify  1  Refute  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 4  Revise  3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 5  Reject  6  Term  35  7  8,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 10  9,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 11  12  31  13  14,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 16  15,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 17  18  32  19  20,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 22  21,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 23  24  33  25  26,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 28  27,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 29  30  34  (a)  Init  Ratify  1  Refute  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 4  Revise  3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 5  Reject  6  Term  35  7  31  13  14,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 16  15  32  19  33  30  34  (b)  Init  Ratify  1  Refute  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 4  Revise  3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=" 5  Reject  6  Term  35  7'," metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 31  13  14-k,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 16-k  15,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=" 17  18  14'," metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=" 16'," metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=" 32  19  33  30'," metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 34  (c)  Figure 3: Message-graph obtained from: (a) transitions listed in Appendix Appendix B;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' (b) the transitions in the  LXP protocol, which is only between compatible agents (Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='4 and (c) the transitions defined in the LXP(k) protocol  (Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 5, in which self-loops in LXP are removed).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  12  (·, ·, µm,i), γn,i = (·, ·, µn,i) where µm,1 = +(n, (Init, ·)) and µ·,k = +(·, (Term, ·)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then, the set  of messages sent from m to n in Smn is Mmn = {τ : there exists i such that µm,i = +(n, τ)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The  set of messages sent from n to m in Smn is Mmn = {τ : there exists i such that µn,i = +(m, τ)}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The messages sent in a session Smn is defined as the pair (Mmn, Mnm).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 7 (One-way Intelligibility).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let (Mmn, Mnm) be the messages sent in a session Smn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  If there exists at least one element (ti, ·) ∈ Mmn s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ti ∈ {Ratify, Refute, Revise} then we will say  Smn exhibits One-Way Intelligibility for m using LXP(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Similarly for One-Way Intelligibility for  n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Definition 8 (Two-Way Intelligibility).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let (Mmn, Mnm) be the messages sent in a session Smn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If  Smn exhibits One-Way Intelligibility for m using LXP(k) and Smn exhibits One-Way Intelligibility  for n using LXP(k) One-Way Intelligibility for n then we will say Smn exhibits Weak Two-Way  Intelligibility for m and n using LXP(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If Smn exhibits Weak Two-Way Intelligibility for m and n  using LXP(k) and there does not exist any (t, ·) ∈ Mmn ∪ Mnm s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' t = Reject then we will say that  Smn exhibits Strong Two-Way Intelligibility for m and n using LXP(k).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Limitations and Clarifications  Although LXP(k) gives us a basis for inferring intelligibility from interaction, it is only a first  step.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The reader would have already identified some limitations, notably:  Execution of LXP(k) requires definition of the LEX functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  As is evident from Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 4,  transitions involve checks and updates that involve significant local computation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Of these  the functions LEARN and EXPLAIN require attention.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We comment on these below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The description of the protocol has been substantially simplified by two assumptions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' First,  that each session will deal with one data-instance at-a-time, and secondly, that the agents  involved in the interaction are compatible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The first restriction means that data containing  multiple examples will require multiple sessions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' While learning and revision of hypotheses  (the LEX function LEARN) is possible with single examples, for example with an on-line learner,  it is more likely that several sessions may be needed to arrive at a suitable hypothesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='7 An  alternative to multiple sessions is to modify messages to include multiple instances, along  with their predictions and explanations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This would then require all the LEX functions to be  modified to account for this change.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The issue of compatibility is related to the notion of  ‘shared knowledge’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The notion of compatibility we have used implies a shared meaning of  when two predictions are similar, and when two explanations agree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It may be possible to  have bounded-length sessions without this common understanding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' At this stage, we do not  know how to achieve this.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  LXP(k) is a synchronous protocol, somewhat like a plain old telephone system (“POTS”).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' That  is, interaction between a pair of agents has to be terminated before commencing a new one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  More elaborate protocols allowing concurrency may be possible, at the expense of greater  7A useful side-effect of single-instance sessions is that it allows the communication of instance-specific explanations  (“this specific data instance has this label because .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ”).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It has been suggested that this is a more effective way for  humans to convey relevant information to a machine-learning engine [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  13  complexity in managing the global configuration of the system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It may require provenance  information to be more detailed (like inclusion of session identifiers and session indices, along  with the sender’s identifier).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The protocol does not account for noise in the channel, delays, or cost of communication  between agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Implementations will need to account for all of these aspects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Finally, although not a limitation of LXP(k), it is nevertheless useful to note that it is common for  protocols to have a preliminary (hand-shaking) phase where some prior information is exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We have not described this aspect in the paper, but it is the phase where LEX agents can establish  some ‘common ground’ needed for ensuring compatibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Note on LEX Functions  The principal LEX functions are in 3 categories: (a) Inference (the function PREDICT);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' (b) In-  duction (the function LEARN);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (c) Justification (the function EXPLAIN).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The Boolean functions  MATCH and AGREE are defined in terms the functions in categories (a)–(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is our position in this  paper that these constitute the basic functionality needed for agents that learn and explain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  One the face of it, it would appear that the LXP(k) protocol requires LEARN to construct hy-  potheses one-instance at a time (that is, the protocol is restricted to on-line learners).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However  this is not the case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is feasible that LEARN may only construct a hypothesis after a reasonable  number of instances have been accumulated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This could be reflected, for example, in the automaton  receiving the instances sending a sequence of messages with Refute tags, and then a message with  a Revise tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Thus, communicating data instance-by-instance does not necessarily mean hypothe-  ses also have to revised instance-by-instance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Assuming that prediction is an important role for a  hypothesis, the requirement of a PREDICT function is unsurprising.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, the MATCH function  can still require some attention.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is straightforward if this is defined by the equality relation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' But  this may not be appropriate for some kinds of predictions like numeric values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If a pair of numeric  values are taken to match is they are within some tolerance factor, then the definition of MATCH  may not satisfy some intuitive properties of equality (like transitivity).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  LXP(k) requires all predictions should be accompanied by explanations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  For some kinds of  agents, like those based on logic, it is possible to identify EXPLAIN with some known descriptors, like  proofs and AGREE can be formulated in terms of well-understood logical operations, like consistency  checking.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For explanations in a less formal setting, like natural language, it is likely that obtaining  a definition of AGREE may require additional effort, and may require models constructed from data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Example 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let am and an be agents that use a logic-based representation, who have exchanged  predicate-definitions encoding their domain-knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Hm be the current hypothesis of am and  Hn be the hypothesis for an.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let predictions of a data-instance x by Hm,n be done by clauses of the  form predict(X, C) ← Body, to be read as “The prediction of any instance X is C if the conditions  in Body are true”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Then possible LEX functions for am (and similarly for an) are;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (a) y = PREDICTm(x, Hm) ≡ (Hm ⊢ predict(x, y)) (where ⊢ is a derivability relation);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (b) LEARNm constructs hypotheses using techniques developed in Inductive Logic Programming  [29];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (c) e = EXPLAINm((x, y), Hm) is the clause in Hm used to derive predict(x, y);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (d) If ym is a prediction by am and yn is a prediction by an then MATCHm(ym, yn) := (ym = yn);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  14  (e) if em is a (clausal) explanation from am and en is a (clausal) explanation from an then  AGREEm(em, en) := (em =θ en) (where =θ denotes an equivalence relation based on the θ-  subsumption as defined in [31]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (These definitions are illustrative, and not the only ones possible with logic-based agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=')  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Role of The Oracle  The oracle ∆ has been used as the source of infallible information about the label for any  data instance x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In any session Sm∆, ∆ receives a message −(m, (Init, (x, ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=', ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='))) denoting a query  about the label and explanation for data instance x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ∆ terminates the session with the message  +(m, (Term, (x, y, ▲))), where y is the oracle’s prediction for the label of x and ▲ denotes that the  explanation is an oracular statement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In our interaction model, ∆ never initiates a session;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and  never sends any message-tags other than Term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  A question that arises is this: if the true labels of data-instances can be obtained directly from  the oracle, why doesn’t a LEX agent communicated just with ∆?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' One aspect we have not considered  in developing the communication protocol is the cost of communication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Collaboration between LEX  agents will be worthwhile if: (a) communication to and from ∆ is significantly more expensive (in  time or money or both) than communication between LEX agents;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (b) the LEX functions of any  one agent can use predictions and explanations from other agents effectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Of these, (a) is likely  to be the case if the oracle is intended to model the acquisition of real-world data by manipulation  and experimentation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The extent to which (b) holds will depend on whether agents are able to  establish some common knowledge, and fulfil the requirements of compatibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The following example shows how collaboration can result in an effective use of either agent’s  knowledge of the oracle’s prediction, thus possibly lessening the cost of communicating to the  oracle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Example 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let m, n be compatible LEX agents with MATCHm(ym, yn) := (ym = yn) and MATCHn(yn, ym)  := (yn = ym).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Smn(x) be a collaborative session between m and n s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Smn terminate with  a Ratify message-tag(correctly, Ratify followed by Term), with Hm, Hn the hypotheses for m, n,  and Dm, Dn be the datasets for m, n respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If (x, y, ▲, ∆) ∈ Dm or (x, y, ▲, ∆) ∈ Dn then  PREDICTm(x, Hm) = PREDICTn(x, Hn) = y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If either m or n has an oracular prediction for x and the session ends with m, n  reaching a consensus on prediction and explanation, then both agents will agree with the oracle’s  prediction for x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This way, it is sufficient for only one of m or n to communicate to ∆ about x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Extending to set of instances X = {x1, x2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' , xk}, the cost of communicating to the oracle can be  reduced for both m and n by restricting oracle-communication for each agent to partitions Xm and  Xn respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' LXP(k) and the Intelligibility Axioms  We now reappraise the Intelligibility Axioms in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1 in terms of communication using LXP(k)  between a human- and a machine-agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We can treat the axioms as a specification (Spec) for  intelligibility and the protocol as an implementation (Impl) for intelligibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Following [15], Impl  correctly implements Spec iff Impl |= Spec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We interpret this to mean that whenever intelligibility  follows from Defn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 7 using LXP(k), intelligibility is inferred using the axioms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It means whenever  15  the LXP(k) protocol communicates Ratify, Refute or Revise tag, the antecedent of one of the axioms  should be true8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' See the table below for the mapping.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Axiom  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='If LXP(k)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Then Axiom’s Antecedent  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Type  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Name  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='action is:  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='must be true:  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='H → M  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine sends  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human explanation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Confirmation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Ratify tag  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='is ratified by machine  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='H → M  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine sends  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human explanation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Refutability  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Refute tag  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='is refuted by machine  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='H → M  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine sends  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human explanation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Performance  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Revise tag  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='improves machine performance  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='M → H  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human sends  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine explanation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Confirmation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Ratify tag  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='is ratified by human  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='M → H  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human sends  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine explanation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Refutability  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Refute tag  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='is refuted by human  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='M → H  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Human sends  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Machine explanation  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Performance  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Revise tag  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='improves human performance  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='Treating interaction between human- and machine as a single session S of communication using  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='LXP(k),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' it is evident that:  (a) If S exhibits One-Way Intelligibility for the machine using LXP(k),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' then we can infer machine-  intelligibility using the H → M axioms;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (b) If S exhibits One-Way Intelligibility for the human using LXP(k), then we can infer human-  intelligibility using the M → H axioms;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (c) If S exhibits Weak Two-Way Intelligibility for human and machine, then we can infer machine-  and human-intelligibility using the H → M and M → H axioms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  By adopting LXP(k) as a protocol, we are immediately assuming compatibility constraints the MATCH  and AGREE functions used by human and machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In fact the design constraints in the table impose  additional constraints on the antecedents of the axioms and the LEX functions MATCH and AGREE and  the actions performed by either agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For example: given the human and machine’s prediction  and explanation, the human’s MATCH and AGREE functions both being true are taken as sufficient  conditions for the machine’s explanation being ratified by human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The most interesting consequence  results from the performance axioms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Take the Machine Performance axiom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If a Revise tag is sent  from the machine to the human, one of MATCH or AGREE for the machine must be false before revision,  and both MATCH and AGREE must be true after revision.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For this to be sufficient for improvement  in machine-performance means that the performance-measure used by the machine depends on the  values of MATCH and AGREE before and after revision.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Related Work  In Appendix Appendix A we referred to a number of sources that are relevant to one or the  other of the Intelligibility Axioms in 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In this section we turn to some other relevant work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' From  8Here the mapping from the actions of the protocol to antecedents of axioms is along the intended interpretation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  16  the framework developed in this paper intelligibility can be seen as a ternary relation involving:  the information-provider, the information provided, and the information-recipient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the literature  on Explainable ML, this has re-emerged as important requirement for the acceptability of ML  (see [26] for a recent example citing earlier work [14], and [24] for an early identification of this).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Furthermore, the explainer and the explainee can be, at different times, the same person or agent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  A large literature has built up over recent years addressing the problems of inscrutable “black-  box” models generated by some modern machine learning techniques which then require mechanisms  for “explainability” [11].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  There are several excellent reviews available on Explainable Machine  Learning (XML), and we refer to the reader to them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' More broadly, the origins of XML can be  found in a prominent DARPA project, launched in 2016 titled “Explainable Artificial Intelligence  (XAI)” [7] which is credited with initiating efforts in XML [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In fact, XAI itself can be viewed as  a continuation of pre-existing research trends: earlier approaches in machine learning largely used  models based on knowledge representations developed in artificial intelligence that were designed  to be interpretable (such as rules, decision trees or logical theories), whereas only recently the drive  for accuracy on ever-larger datasets has led to models that require explanation [34].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The DARPA project used the term “explainability” to denote the use of techniques to generate  an explanation for a model [13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A distinction can therefore be made between interpretable models,  which are constrained to work in a way that is (at least, in principle) understandable to humans, and  explainable methods, which are applied to the results obtained from black-box models [34].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This  difference is similar to the distinction made between model transparency and post hoc explainability  for black-box models [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, interpretability is not simply a property of a class of models,  but also of the data, feature engineering, and other factors, and, as such, it may be difficult  to achieve in applications [21, 34].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Explainability by post hoc methods suffers from problems  of approximation, since the explainable model is not usually the model responsible for making  the predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Recent criticism of post hoc explainability suggests such methods should not be  adopted for certain medical [3] and legal [45] applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  In particular, it appears that such  explanations may not be able to satisfy the legislative requirements for avoidance of discrimination,  for example [45]  In presentations of the problem of explainability it is usually assumed there is a human to which  a machine is providing the explanation, in the terminology we have used in this paper, this means  One-Way Intelligibility for the human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Even in this limited setting, considering only techniques for  explanation ignores other issues, like the role of the explainee, for whom the explanation is intended,  which is contrary to evidence from social science [26].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For instance, the diversity of explainees  suggests thinking of explanation in terms of the understanding of the explainee [39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' From this  standpoint [38, 39] propose that explanation should be a bi-directional process rather than a one-  off, one-way delivery of an explanation to a recipient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Therefore explainability is a process involving  reasoning over interpretable insights that are aligned with the explainee’s background knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The proposal is that an explainer should allow explainees to interact and rebut explanations;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' in  the proposed framework the entire explanatory process is based on a reasoning system enabling  communication between agents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We are aware of at least two threads of work in the ML literature that recognises some of the  aspects just described.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In Argument-Based ML, or ABML [47, 27], data provided by a human to  an ML engine includes explanations formulated in terms of background knowledge shared between  human and machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' These explanations constitute ‘arguments’ for the label for data instances,  and the ML system attempts to construct hypotheses that are consistent with the explanations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Learning from explanations was employed by early ML systems like MARVIN [35] that performed  17  supervised-learning in the original sense of a human guiding the construction of hypotheses by a  machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The learning protocol employed in such systems is naturally interactive, involving human-  presentation of data along with explanations (if any), and revision of hypotheses by machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The  interaction can result in Two-Way Intelligibility if interactions consist of human refutation of a  machine’s explanations;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and the machine revises its hypothesis in response.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, no refutation  of the human’s explanation is envisaged within ABML nor any revision of his or her hypothesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  A second thread of work is that on Explanatory Interactive Learning (XIL: [43, 40]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Although  the methods proposed in [39] allow the human to interact with the machine learner, this approach is  more fully realised in XIL, with the implementation of a revision capability based on the combination  of active machine learning with machine-to-human explainability interaction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The ML component of  XIL uses active learning to identify an “informative” (unlabelled) instance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This instance is labelled  by the machine’s hypothesis, and an explanation is then generated While the specific mechanism  for generating an explanation is not important, XIL does require the prediction and explanation to  be characterised into one of 3 categories by a human-in-the-loop: (i) “right for the right reasons”;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (ii) “wrong for the wrong reasons”;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (iii) “right for the wrong reasons” [33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Nothing is done  in categories (i) and (ii), but category (iii) initiates a revision of the machine’s hypothesis using a  range of XAI techniques [42]9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  In work on XIL applications to computer vision, where the learner is implemented by a deep  network, the key intermediate step of defining “concepts” was implemented to better communicate  with the human to enable any required revisions [40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='10  The characterisation predictions and explanations in XIL is similar in spirit to the categories  defined by the guard functions in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' As with ABML, an XIL system demonstrates Two-  Way Intelligibility when the human provides refutations (in XIL, this is done by augmenting the  data) and the machine revises its hypothesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Also in common with ABML, the machine does not  provide refutations for the human’s prediction and/or explanation, and revision of the human’s  hypothesis is not envisaged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Finally, although not cast either as ABML or XIL, but nevertheless  related to aspects of both are implementations of incremental learning designed human-machine  collaboration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Recent examples of collaboration using symbolic ML are in [32] for applications  to computer security, and using a combination of neural and symbolic learning for collaborative  decision-making systems for medical images [36]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Again, these approaches exhibit a form of two-  way intelligibility, since they rely on the human providing refutations and the machine improving  its performance as a result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Concluding Remarks  In this paper we have sought to look beyond the current practice in Explainable Machine Learn-  ing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is our contention that for problems which are sufficiently complex that neither human nor  machine have complete answers, designers of ML-based decision-support tools must be concerned  with mutual intelligibility of information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Based on this position, we have sought to characterise  9The category “wrong for the right reasons” does not appear to have been addressed in XIL.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  10Such concept-based explainability methods have also been applied more widely for deep learning [46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  For  example, concept-based explanations have recently been applied in an attempt to comprehend the chess knowledge  obtained by AlphaZero, and concluded that this approach did reveal a number of relationships between learned  concepts and historical game play, from standard opening moves to tactical skills, as assessed by a former world  chess champion [23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This is an illustration of the phenomenon predicted by Michie (see above, Thompson’s table).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  18  intelligibility as a property of interaction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For the design of ML systems with humans-in-the-loop  this means both a human and a machine need to provide explanations in a form that the other can  inspect and evaluate critically, and respond meaningfully to that evaluation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  But the requirement is easier to state than to achieve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' There are 3 aspects to consider: (a)  The representation used by either side for explanations;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' (b) How to evaluate critically;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and (c) The  rules of communicating the result of evaluation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In this paper, we have focused on (c), with the  goal of inferring intelligibility from the messages exchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Nevertheless, we comment on (a) and  (b) below, since they are relevant to LEX agents of the kind we consider in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Aspect (a) is concerned with on how human knowledge about the world should be represented  in order to be useful to a machine, and vice versa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' McCarthy [22] envisaged this would be done as  statements in a formal language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' But this does not have to be necessarily the case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For example,  it may be sufficient for information provided by the human to transform some or all of the inputs  of the ML system, like the data, utility function, structure or parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, we do not  as yet have a way to do this satisfactorily for all kinds of formal languages and all kinds of ML  systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the short- to medium-term therefore, we believe this will require the human decision-  maker may have a working knowledge of the ML system, or to employ someone who does.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the  longer term, neither of these options are practical, and decision-support tools will need mechanisms  to receive information in natural language, and perform any manipulations to its inputs internally.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Some progress is being made on processing information in a natural language (see for example,  [41]), but we are still far from being able to do this well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Assuming we have the human-supplied  information in some machine-usable form, the machine may still need to ask the decision-maker  questions to clarify any ambiguities or inconsistencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' To resolve these would undoubtedly need  the machine to be able to generate its own data, and ask questions about them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' How should it  represent these questions?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Again, in the long-run, natural human-computer interaction techniques  seem inevitable [6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The problem in (b) is concerned with the human evaluation of a machine’s explanation, and  vice versa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human evaluation would clearly be easier if the explanation employed concepts that  the human can recognise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the near-term, the machine can achieve this in one of two ways.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' First,  the machine can elect to employ only those concepts that are already known to the human.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The  identification of Covid patients in the previous section is an example: the features extracted from  chest X-rays were restricted to those identified by a radiologist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A second way is for the machine to  show instantiations through some textual or visual means.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For example, ML systems that attempted  to discover chess concepts showed board positions exemplifying the concept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The chess-expert may  then be able to map the machine-identified concept to some part of their chess vocabulary (such  as “this is really about Kings in opposition”).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the long-term, as the problems, data and ML  systems get more complex, it may not be possible to engineer an adequate set of shared concepts  beforehand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Establishing what exactly a concept ‘invented’ by the machine really means will be a  challenging task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The converse problem, of critical evaluation of a human explanations may prove  more amenable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' If the explanations are translatable into a formal language, then tools developed  for model- and proof-checking can be adapted to the task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The recent promise large-scale language  models suggests that even if explanations are in a natural language, it may be possible to develop  language models for approximating idealised forms of logical reasoning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Aspect (c)–when and what to communicate–is the most amenable to analysis, given the long  history of developing communications protocols.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Surprisingly, although there is little dispute that  explanations are intended to be communicated, little attention to paid to effective interaction  between the agents constructing the explanations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We identify effectivity with intelligibility, and  19  show how this can be postulated as a property of a communication protocol between agents capable  of learning to predict and explaining the predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  We suggest that the design of ‘two-way  intelligibility’ protocols should be part of the design and analysis of Explainable AI (XAI) systems  from the ‘ground-up’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is not coincidental that three of the R’s we have identified here — Refute,  Revise, and Ratify — are at the heart of advancing understandability in Science.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We suggest they  may play a similar role in evolving a shared understanding of data by human-machine systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Acknowledgements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  AS is a Visiting Professor at Macquarie University, Sydney and a Visiting Professorial Fellow  at UNSW, Sydney.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  He is also the Class of 1981 Chair Professor at BITS Pilani, Goa, the Head of the Anuradha and  Prashant Palakurthi Centre for AI Research (APPCAIR) at BITS Pilani, and a Research Associate at TCS Research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' MB  acknowledges support in part by Rich Data Co.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Pty and the Australian Government’s Innovations Connections scheme  (awards ICG001855 and ICG001858).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' EC is supported by an NHMRC investigator grant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Many of the results reported  here are from collaborative work done by the authors with colleagues at several institutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We would especially like to  acknowledge the role played by: Tirtharaj Dash, Rishabh Khincha, Soundarya Krishnan, Lovekesh Vig, Arijit Roy, Gautam  Shroff, Paul Compton, Ross King and Stephen Muggleton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' AS and MB owe a debt of gratitude to Donald Michie, who  shaped much of their thinking on the views expressed in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
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+page_content=' Baskar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Inclusion of domain-knowledge into GNNs  using mode-directed inverse entailment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
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+page_content='  [9] Tirtharaj Dash, Ashwin Srinivasan, Ramprasad S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
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+page_content='  In Igor V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
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+page_content=' Springer, 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  20  [10] M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Ghassemi, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Oakden-Rayner, and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
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+page_content=' Explainable artificial intelligence (XAI) post-hoc explain-  ability methods: risks and limitations in non-discrimination law.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' AI Ethics, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  [46] C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='-K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Yeh, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Kim, and P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Ravikumar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human-Centered Concept Explanations for Neural  Networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Hitzler and K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Sarker, editors, Neuro-Symbolic Artificial Intelligence: The  State of the Art, volume 342 of Frontiers in Artificial Intelligence and Applications, pages  337–352.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' IOS Press, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  [47] J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Zabkar, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Mozina, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Videcnik, and I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Bratko.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Argument based machine learning in a  medical domain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In Computational Models of Argument, pages 59–70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' IOS Press, 2006.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Examples of Machine- and Human-Intelligibility  Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Machine-Intelligibility  Example 4 (The Machine-Confirmation Axiom).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In [27], the authors suggest that a human pro-  vides data-instances provided to the ML engine are either the usual pairs (x, yh), in which yh is the  human’s label for the data-instance x;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' or triples (x, yh, eh), in which eh is human’s explanation (the  authors use the term ‘argument’) for the label yh for x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The task of the ML engine is to construct  a hypothesis which attempts to ensure that the prediction ym made by the hypothesis and the asso-  ciated explanation em ar such that if yh = ym then eh and em are consistent with each other (for  the representation used in [27] consistency-checking can be can be done efficiently using a logical  formulation).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This can be seen as a form of confirmation of the human’s prediction and explanation  by the machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The authors demonstrate the applicability of this form of ‘Argument-Based ML’ to  the problems from the legal profession, and to business problems involving credit-risk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Example 5 (The Machine-Refutability Axiom).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In [19], the authors describe a Robot Scientist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  This is a robotic system that executes cycles of hypothesis formation, wet-lab experimentation to to  test conjectures, execution of experiments, and refutation of hypotheses based on the results of the  experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In [19], the robot scientist ‘Adam’ starts with a hypothesis about the aromatic amino-  acid (AAA) pathway in yeast (S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' cerevisiae).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Adam was given a hypothesis representing existing  23  Figure A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='4: A portion of the prior hypothesis about the AAA pathway in yeast provided by the biologist to the  robot scientist Adam (from [19]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  biological knowledge about the AAA pathway.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This knowledge is a directed graph with metabolites as  vertices in the graphs and enzymes as edges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' An edge corresponds to a reaction (that is, reactions  unidirectionally transform metabolites).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A fragment of this graph is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Adam then proceeds to conduct a sequence of (self-constructed) laboratory experiments to test  the hypothesis;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and returns a new hypothesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The new hypothesis contains additional edges that  correctly explain observational data obtained from the experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the natural sciences, the  terms ‘hypothesis’ and ‘explanation’ are used interchangeably.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In a Popper-like approach to scientific  discovery, replacing a hypothesis with a new one entails a refutation of the older hypothesis by the  new one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In this sense, Adam is seen as ‘refuting’ the prior explanation for the AAA pathway, and  replacing it with a newer explanation for the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Example 6 (The Machine-Performance Axiom).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We show first recent results reported in [8, 9] in  the area of drug-design.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' This is well-known to be a time-consuming and expensive process, requir-  ing the involvement of significant amounts of human chemical expertise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' ML-based models have  been used to assist in this by constructing models relating chemical structure to molecular activity  (like binding affinity, toxicity, solubility and so on), and even in the generation of entire new small  molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The experiments reported consider the construction of predictive models using relations  which are typically used to construct human-understandable explanations (like known chemical ring  structures, functional groups, motifs and the like).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The data provided were in the form of “most-  specific explanations” for molecules using the domain-knowledge (these were constructed automat-  ically using a technique developed in Inductive Logic Programming [28]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The machine-learning  systems considered are two kinds of deep neural networks (a multi-layer perceptron, or MLP, and  a graph neural network, or GNN).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Figure A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='5 tabulates the number of datasets on which perfor-  mance improvements are observed, with the inclusion of human domain-knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For each deep  network type, for problems in the “Better” column, the machine uses the information provided to  improve performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In each such instance, the machine-performance axiom will infer that the  domain-knowledge is intelligible to the machine, but says nothing about the remainder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Perhaps the earliest use of human domain-knowledge to improve the performance of a ML pro-  gram is found in DENDRAL [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The DENDRAL program attempts to solve the ‘inverse’ problem  of constructing possible structures of organic molecules that could result in data observed in a mass  spectrogram (the mass spectrogram for uncontaminated water, for example, would show a single  24  Glyceraie-  2-phosphate  人  Metabolite  YGR254W  YHR174W!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  YMR323W  Phosphoenol  pyruvate  5-o-1-Carboxyvinyl-  YBR249C  YDR127W  3-phosphoshikimate  Arthranilate  YDR035W  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  YER090  Dino-  YGL148W  YKL2110  7-phosphate  Chorismate  YPR060C  YDR127W  Shikimate-3-  chosohate  uinate  Prephenate  YDR127W  YDR127W  YBR166C  YNL3160  ikimateComparative Performance  DNN  (with domain-knowledge)  Type  Better  Same  Worse  MLP  71  0  2  GNN  63  9  1  Figure A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='5: The use of domain-knowledge by two kinds of deep neural networks (DNNs): mult-layer perceptrons  (MLPs) and graph-neural networks (GNNs).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Estimates of performance are obtained on 73 different datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Here,  “Better” (respectively, “Same” and “Worse”) means the use of domain-knowledge results in an improvement in  performance (respectively, no change, and worse performance).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  peak at 18, suggesting the structure H2O).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The DENDRAL program employed a complete and cor-  rect generator of molecular structures, but to identify accurate hypothesis the heuristic search used  human knowledge that encoded chemical constraints and information on mass spectrometry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='11  Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human-Intelligibility  Example 7 (The Human-Confirmation Axiom).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The tabulation of the radiologist’s assessment of  machine explanations generated for Covid in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' 1 shows there are 17 instances where the radiologist  thinks the explanation is sufficient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In all such cases, the human-confirmation axiom would infer  that the corresponding explanations were intelligible to the radiologist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  In the example described earlier on the Robot Scientist, the prior hypothesis provided for the  AAA pathway was in fact known in advance to be incorrect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Substantially more additions to the  existing knowledge about yeast by Adam was reported in [18], in which Adam identified the functions  of several novel hypotheses concerning the identity of genes encoding enzymes in metabolic pathways  in yeast.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' These hypotheses were later confirmed by gold-standard experiments constructed by human  scientists in the laboratory, making it possibly the first-of-a-kind result of scientific discovery by a  ML engine accompanied by confirmation by human specialists.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Example 8 (The Human-Performance Axiom).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Michie’s “Ultra-Strong” criterion for machine  learning stipulates that a machine must be able not only to output its hypotheses in symbolic form  but also enable humans, given some study time, to subsequently apply them and thereby improve  their performance [24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In [30] for the first time a set of operational definitions of the Ultra-Strong  criterion were developed, based on the use of an Inductive Logic Programming (ILP) to learn sym-  bolic hypotheses in the form of logic programs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Since pure logic programs can be read as declarative  concept definitions they are, at least in principle, humanly-understandable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Comprehensibility was  defined as a predicate with two arguments, a definition or logic program P and a sample of human  subjects S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Comprehensibility of P is then quantifiable in terms of the mean accuracy of human  subjects from S on prediction tasks containing unseen data from the same problem domain as the  training data However, several additional operational definitions were introduced to characterise  comprehensibility, for example, the textual complexity of concept definitions, and time taken for  humans to study training data and concept definitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Empirical evaluation of human performance was in terms of predictive accuracy on a problem  based on the recursive definition of an ancestor in a family tree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' However, to control for effects  11DENDRAL is also an early example of building an ‘expert system’ using machine learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Contrary to a popular  (mis)conception, there is a long history of constructing such systems by machines, with assistance from humans.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  25  due to prior background knowledge, this was presented to the human participants as a problem in a  fictitious domain concerning statements about exothermic chemical reactions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Human participants  were split into two groups.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The first group was tested on their ability to correctly classify examples  from the chemistry domain after being exposed to the training data alone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  However the second  group was provided, in addition to the training data, with rules learned by the ML, and then their  predictive ability was tested in the same way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' For the ML to satisfy the Ultra-Strong criterion, the  performance of the first group should be significantly lower than that of the second group, which was  the result reported in [30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Automaton Transitions in a Session  We assume a session Smn in which the automaton an receives a message µ from am;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' executes code  Π = (D′  n := Dn ∪ {(x, ym, em, m)} ∧ P ∧ yn := PREDICT(x, Hn) ∧ en := EXPLAIN((x, yn), Hn) ∧  y′  n := PREDICT(x, H′  n)  ∧  e′  n := EXPLAIN((x, y′  n), H′  n);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' checks guard g;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' and sends message µ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The transition system can be represented as a set of 4-tuples (γ, Π, g, γ′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Here γ and γ′ are  (global) configurations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We tabulate below the set of transitions when an sends a message to am  (the transitions for am can be obtained by interchanging an and am).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' The global configurations  are γ = ((Hm, Dm), +(n, µ), (Hn, Dn), −(m, µ)) and γ′ = ((Hm, Dm), −(n, µ′), (H′  n, D′  n), +(m, µ′)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Below we tabulate only µ, P, g, and µ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' LEARN(Hn, ·, ·) returns Hn if no suitable generalisation is  found.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the tabulation below, if H′  n = Hn then y′  n = yn and e′  n = en.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In the tabulation, g′ =  MATCHn(y′  n, ym) ∧ AGREEn(e′  n, em).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  26  Trans  µ (received by an)  P  g  µ′ (sent by an)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  No message  H′  n := Hn  ⊤  (Init, (x, y′  n, e′  n))  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  15.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := Hn  g1  (Ratify, ((x, y′  n, e′  n))  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g2 ∧ g′  (Revise, ((x, y′  n, e′  n))  28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ ¬g′  (Refute, ((x, y′  n, e′  n))  29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  g3 ∧ g′  (Revise, ((x, y′  n, e′  n))  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := Hn  g4  (Reject, ((x, y′  n, e′  n))  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Ratify, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Refute, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Revise, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Reject, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Init, (x, ym, em))  H′  n := Hn  ⊤  (Term, (x, y′  n, e′  n))  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Term, (x, ym, em))  H′  n := LEARN(Hn, D′  n)  em = ▲  No message  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  (Term, (x, ym, em))  H′  n := Hn  em ̸= ▲  No message  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let ψ be an execution of the LXP protocol in a session between compatible agents  am and an.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The transitions correspond to rows 8,9,10,11 and 12 will not occur in ψ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The transitions correspond to rows 20,21,22,23 and 24 will not occur in ψ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  The transitions correspond to rows 25,26,27,28 and 29 will not occur in ψ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We assume each of the above transitions represents a communication of the message µ′ =  (t′, x, y′  n, e′  n)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Without loss of generality, we assume that n is the sender and m is the receiver  27  of this communication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' We observe that the message tag in the above communication is different  from Init.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' So it is immediately preceded by other transitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' These preceding transitions would  represent communications in which the agent m sends the message µ = (t, (x, ym, en)) and the  agent n receives it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Hm and Hn be the hypotheses of m and n before communicating the  message µ, H′  m and H′  n be the hypotheses of m and n after communicating µ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' H′  n be the updated  hypothesis of n after receiving the message m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Also observe that ym := PREDICT(x, Hm), em :=  EXPLAIN((x, ym), Hm), y′  n := PREDICT(x, H′  n) and e′  n := EXPLAIN((x, y′  n), H′  n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Hm, ym, em  Hn, yn, en  Hm, ym, em  H′  n, y′  n, e′  n  H′  m, y′  m, e′  m  H′  n, y′  n, e′  n  m sends µ  n receives µ  n sends µ′  m receives µ′  n checks the guards using  MATCHn(yn, ym), AGREEn(en, em)  MATCHn(y′  n, ym), AGREEn(e′  n, em)  m checks the guards using  MATCHm(ym, y′  n), AGREEm(em, e′  n)  MATCHm(y′  m, y′  n), AGREEm(e′  m, e′  n)  Now let us consider the transitions 8,9,10,11 and 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is clear that the message tag t in each  of these transitions is Ratify.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It means the previous transition should be any one of 1,7,13,19  and 25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Also there is no change in the hypothesis of the agent m and the previous transition’s  guard MATCHn(yn, ym)∧AGREEn(en, em) is true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Since this is a collaborative session, the guard  MATCHm(ym, yn) ∧ AGREEm(em, en) is also true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Hence the guards for 8,9,10,11 and 12 are all  false and these transitions will never occur in any collaborative session using the LXP protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Now let us consider the transitions 20,21,22,23 and 24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is clear that the message tag t in  each of these transitions is Revise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It means the previous transition should be any one of  3,5,9,11,15,17,21,23,27 and 29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' In all theses transitions, the guard g′ (which is MATCHn(y′  n, ym)∧  AGREEn(e′  n, em) is true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Since this is a collaborative session, the guard MATCHm(ym, y′  n) ∧  AGREEm(em, e′  n) is also true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Hence the guards for 20,21,22,23 and 24 are all false and these  transitions will never occur in any collaborative session using the LXP protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Now let us consider the transitions 25,26,27,28 and 29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It is clear that the message tag t in  each of these transitions is Reject.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' It means the previous transition should be any one of  6,12,18,24 and 30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Also there is no change in the hypothesis of the agent m and the previous  transition’s guard ¬MATCHn(yn, ym) ∧ ¬AGREEn(en, em) is true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Since this is a collaborative  session, the guard ¬MATCHm(ym, yn) ∧ ¬AGREEm(em, en) is also true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Hence the guards for  25,26,27,28 and 29 are all false and these transitions will never occur in any collaborative  session using the LXP protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  Remark 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let Smn be a collaborative session between agents am and an consisting of a sequence  of configurations ⟨γ1, γ2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' , γk⟩, where γi = (γm,i, γn,i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content=' Let γm,i = (·, ·, µm,i), γn,i = (·, ·, µn,i)  where µm,1 = +(n, (Init, ·)) and µ·,k = +(·, (Term, ·)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  If there is an i such that the message tag in µm,i or µn,i is Ratify, then for each j such that  i < j < k, rj = rj−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  28  If there is an i such that the message tag in µm,i or µn,i is Reject, then for each j such that  i < j < k, rj = rj−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
+page_content='  29' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/a9AzT4oBgHgl3EQf2v6K/content/2301.01819v1.pdf'}
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+Thermal dependence of the hydrated proton and
+optimal proton transfer
+F´elix Mouhat,1 Matteo Peria,2
+Tommaso Morresi,3 Rodolphe Vuilleumier,4
+Antonino Marco Saitta,2 and Michele Casula2∗
+1Saint Gobain Research Paris,
+39, Quai Lucien Lefranc, 93300 Aubervilliers, France
+2IMPMC, Sorbonne Universit´e, CNRS, MNHN, UMR 7590,
+4 Place Jussieu, 75252 Paris, France
+3 ECT*-Fondazione Bruno Kessler∗,
+286 Strada delle Tabarelle, 38123, Trento, Italy
+4 ´Ecole normale sup´erieure, PSL Research University,
+Sorbonne Universit´e, CNRS, D´epartement de Chimie, PASTEUR,
+24 Rue Lhomond, 75005 Paris, France
+∗To whom correspondence should be addressed; E-mail: michele.casula@upmc.fr.
+Water is a key ingredient for life and plays a central role as solvent in many
+biochemical reactions. However, the intrinsically quantum nature of the hy-
+drogen nucleus, revealing itself in a large variety of physical manifestations,
+including proton transfer, gives rise to unexpected phenomena whose descrip-
+tion is still elusive. Here we study, by an unprecedented combination of state-
+of-the-art quantum Monte Carlo methods and path-integral molecular dy-
+namics, the structure and hydrogen-bond dynamics of the protonated water
+hexamer, the fundamental unit for the hydrated proton. We report a remark-
+1
+arXiv:2301.01825v1  [cond-mat.mtrl-sci]  4 Jan 2023
+
+ably low thermal expansion of the hydrogen bond from zero temperature up to
+300 K, owing to the presence of short-Zundel configurations, characterised by
+proton delocalisation and favoured by the synergy of nuclear quantum effects
+and thermal activation. The hydrogen bond strength progressively weakens
+above 300 K, when localised Eigen-like configurations become relevant. Our
+analysis, supported by the instanton statistics of shuttling protons, reveals that
+the near-room-temperature range from 250 K to 300 K is a “sweet spot” for
+proton transfer, and thus for many phenomena depending on it, including life.
+1
+Introduction
+For more than 200 years and the seminal work of von Grotthus, the properties of the hydrated
+proton H+
+(aq) have intrigued the scientific community [1, 2]. Despite significant advances, the
+exact role of the solvated proton in proton transfer (PT) reactions in chemical and biological
+systems is not fully elucidated yet. The textbook picture is that the hydrated proton exists as
+classical hydronium cation H3O+, but it looks more appropriately described as a delocalised
+charge defect shared by multiple molecules. The spread of this charge defect blurs the identity
+of the excess proton among two limiting structures, namely the Zundel[3] and the Eigen[4] ions.
+Indeed, the hydrated proton Infrared (IR) spectrum displays a combination of a few discrete
+absorption bands on top of an absorption continuum, broadly extended over the entire spectrum.
+Neither the symmetrically solvated hydronium H9O+
+4 (Eigen) ion, nor the equally shared proton
+in the H5O+
+2 (Zundel) ion, can individually rationalise this characteristic IR fingerprint. Models
+involving fast inter-conversions between these two ionic species are also shown to fail[5].
+To deal with these issues, Stoyanov et al.[6] have introduced the stable H13O+
+6 species, the
+protonated water hexamer, which is Zundel-type in the sense that the excess proton is equally
+shared between two water molecules. The core of the cluster is characterised by a central
+2
+
+oxygen-oxygen distance dO1O2 that, however, is more elongated than in the Zundel cation[7].
+On the other hand, recent Molecular Dynamics (MD) simulations suggest the existence of a
+distorted, nonsymmetric Eigen-type cation, remaining at the heart of a dynamical charge defect
+spanning multiple water molecules [8]. Thus, the protonated water hexamer represents the
+smallest protonated water cluster for which both of these characteristic binding motifs coexist[9,
+10]. It is the simplest one that can provide a meaningful description of the hydrated proton in
+water. The main protonated hexamer configurations are represented in Fig. 1, for both Zundel-
+and Eigen-like forms.
+The protonated hexamer Potential Energy Surface (PES) has been partially explored by
+IR spectroscopy [11, 12, 13] and electronic structure calculations performed within Density
+Functional Theory (DFT), Møller-Plesset (MP2), and Coupled Cluster (CC) approaches, also
+supplemented by Machine Learning techniques, [14, 12, 9, 11, 15, 16] confirming that the two
+structures introduced above are the lowest energy isomers. The quantum nature of the proton
+however induces a delocalised structure on this PES.
+In this work, we apply MD simulations fully retaining the nuclear quantum nature of the
+atoms. In particular, the quantum proton, described within the Feynman path integral (PI) ap-
+proach, evolves in a very accurate PES estimated by means of Quantum Monte Carlo (QMC).
+This stochastic technique introduces an intrinsic noise, which affects the forces driving the ion
+dynamics and, consequently, the simulation temperature. Relying on the generalised fluctuation-
+dissipation theorem, a Langevin-based approach has been developed to address this issue for
+classical [17] and quantum [18] ions. It allows one to sample microscopic configurations in the
+canonical ensemble with an unprecedented level of quantum accuracy. Details of the method
+are provided in the Methods Section and in Secs. S1 and S2 of the Supplementary Information
+(SI).
+We find that the hydrogen bond (H-bond) mediated by the hydrated proton shows a remark-
+3
+
+ably low thermal expansion from zero temperature up to 300 K, with a nearly temperature-
+independent length that becomes shorter than the classical-ion counterpart in the [200-350] K
+temperature range. A non-trivial behaviour of the H-bond has also been found in H-rich crys-
+tals and ferroelectric materials, such as the potassium dihydrogen phosphate (KDP)[19], first
+detected by Ubbelohde in 1939 upon isotopic substitution[20]. In the latter case, the lighter the
+hydrogen, the shorter the H-bond. This was interpreted as a quantum manifestation of proton
+delocalisation, strengthening the H-bond. In the present situation, the strength of the H-bond re-
+sults from a non-trivial cooperation of nuclear quantum effects (NQEs) and thermal activation,
+as we will show in this work. Indeed, NQEs strongly affect the vibrational levels of the proton
+shuttling mode bridging the central O1 and O2 oxygen atoms. These levels are then thermally
+occupied according to the dO1O2 distance of a given configuration. We can thus distinguish three
+regimes (see Fig. 1): (i) “short-Zundel” configurations with the shortest dO1O2, where the shut-
+tling proton feels a quadratic potential and it is perfectly shared between the two central water
+molecules; (ii) “elongated-Zundel” configurations for intermediate dO1O2, comprising the equi-
+librium distance, where a potential energy barrier starts to develop in between O1 and O2 and
+the proton is delocalised only due to NQEs; (iii) “distorted-Eigen” configurations at even larger
+dO1O2, where the central barrier is large enough that the hydrated proton is localised on one of
+the two flanking water molecules, forming an Eigen-like complex. We will see that the occur-
+rence of short-Zundel configurations is key to understand the H-bond thermal robustness and
+to enhance the proton transfer dynamics. Despite being energetically disfavoured by the short
+dO1O2 distances at the classical level, these configurations are populated thanks to the synergistic
+action of NQEs and temperature, yielding a sweet spot for proton transfer in the [250-300] K
+temperature range.
+4
+
+2
+Results and discussion
+Thermal expansion of the H-bond
+To rationalise our main outcome, we first study the zero-
+temperature classical geometry and PES of the protonated water hexamer, and compare it with
+the Zundel cation. While the latter system misses a large part of water solvation effects, the
+former includes the full contribution of the first and second shells of the solvated proton. The
+zero-temperature results are reported in Sec. S3.1 of the SI. We simply highlight here that the
+Variational Monte Carlo (VMC) equilibrium O1-O2 distance is found to be dO1O2 = dmin =
+2.3930(5) ˚A, in good agreement with MP2 calculations, the most widely used post Hartree-
+Fock theory to study water clusters (see Sec. S1.2 of the SI for a more extended comparison
+between VMC and MP2). VMC has a milder scale with the system size than MP2, allowing
+one to perform extensive calculations of the protonated hexamer. At variance with the Zundel
+cation[21, 22], the protonated hexamer equilibrium geometry is asymmetric, implying that the
+global minimum is split into a double well, separated by an energy barrier between the two
+central water molecules. This barrier vanishes at dO1O2 = dsymm ≃ 2.38 ˚A, a distance that
+separates the short Zundel below from the elongated-Zundel configurations above. The height
+of the barrier is less than 100 K (in kB units) at dmin, rapidly increasing as a function of dO1O2. We
+therefore expect several consequences on the hydrated proton distribution and on its mobility at
+finite temperature, once the NQEs are taken into account.
+To understand how the dynamics of the hydrated proton evolves with temperature, QMC-
+driven ab initio MD simulations are relevant. Such calculations are carried out for both classical
+and quantum nuclei of the H13O+
+6 ion, within the temperature interval T ∈ [50 − 350] K, thanks
+to the methodological developments detailed in Ref.[18] and in the Methods Section. At these
+conditions, the clusters are stable during the simulated time frame (≈ 30 ps), allowing us to
+access the thermal properties of the hydrated proton and the O1H+O2 bond over an extended
+5
+
+temperature range.
+From our QMC-MD simulations, we extract the normalised Pair Correlation Functions
+(PCFs) gO1O2 for the two oxygen atoms O1 and O2 of the cluster core (Fig. 2). The expected
+broadening of the PCFs due to nuclear quantisation is significant over the whole temperature
+range (Fig. 2(b)). Only at temperatures as high as 350 K, the classical gO1O2 (Fig. 2(a)) starts
+resembling the quantum distribution. This implies that the NQEs cannot be neglected for tem-
+peratures up to this value, above ambient conditions. We also notice that, when comparing to
+the Zundel ion results[23], the peak position is shifted up by at least ∼ 0.01 ˚A. Thus, it ap-
+pears that the H13O+
+6 cluster frequently adopts elongated-Zundel configurations[24, 25, 26] at
+the lowest temperatures considered here. This is at variance with the protonated water dimer,
+where the hydrated proton lives in a single minimum symmetrically located between the two
+water molecules.
+Focusing our attention to ⟨dO1O2⟩ (Fig. 2(c)), its classical and quantum behaviours are re-
+markably different as a function of temperature. On the one hand, the classical dO1O2 keeps
+increasing with temperature, as more energy is given to the intermolecular vibration modes. On
+the other hand, the quantum dO1O2 displays a nearly flat behaviour with the cluster temperature,
+up to 300 K. This very low thermal expansion extended over a wide temperature range leads
+to a temperature regime where dO1O2 for the quantum system become shorter than the classical
+values at the same temperatures. This is clearly seen in Fig. 2(c). We will come back to this
+point later.
+Finally, as the temperature further increases, the NQEs reduction weakens the central H-
+bond strength. Consequently, dO1O2 spreads out, due to stochastic fluctuations of the core and
+the solvent, and a more classical regime is reached, when the averaged dO1O2 values for classical
+and quantum nuclei meet again. The PCF distributions display longer tails, with more config-
+urations covering regions with dO1O2 ∈ [2.5 − 2.7] ˚A, and the peak position rapidly shifts to
+6
+
+larger values. Configurations with such a large ⟨dO1O2⟩ are of distorted-Eigen type[24, 27].
+A cooperative thermal-quantum species: the short-Zundel ion
+To refine our structural
+analysis, we compute the bidimensional distribution function ρ2D, which correlates the oxygen-
+oxygen (O1O2) and the oxygen-proton (O1/2H+) distances, and study its temperature depen-
+dence ρ2D = ρ2D(T). In Fig. 3, we show the contour plot of the temperature-driven ρ2D
+variation (see also Sec. S3.2 of the SI). By taking ρ2D(250 K) as reference, four temperature
+variations are explored: 100 K, 200 K, room temperature (RT), and 350 K (from the top to the
+bottom of Fig. 3).
+In the classical protonated hexamer (Fig. 3, left column), rising the temperature from 250
+K up to 350 K tends to stretch ⟨dO1O2⟩, by promoting configurations from the elongated Zundel
+(blue central distribution with dO1O2 ∈ [2.38, 2.5] ˚A in Fig. 3) to an Eigen-like arrangement
+with larger dO1O2 and a proton much more localised on one of the two central oxygen atoms
+(red wings). The situation is reversed at lower temperatures (100 K and 200 K) if compared to
+the 250 K reference, with positive (red) variations in the elongated Zundel and negative (blue)
+variations in the wings. Thus, for classical nuclei, there is a progressive depletion of the elon-
+gated Zundel and a corresponding population of the distorted-Eigen wings upon temperature
+rise. Short-Zundel configurations, highlighted in Fig. 3 by a gray background, seem to play a
+very marginal role in the temperature-driven density distribution shift.
+The scenario is strikingly different with quantum nuclei (right column), particularly at the
+lowest temperatures (100 K and 200 K). In this regime, distorted-Eigen configurations are barely
+populated or depleted, and the density shift upon rising temperature takes place between the
+elongated-Zundel region and the short-Zundel sector. The latter is significantly more populated
+at 250 K than at lower temperatures at the expense of the elongated Zundel, which instead loses
+density with respect to the classical counterpart at the same temperature.
+7
+
+In the higher-temperature limit, at 350K, NQEs are less relevant and, by consequence,
+the classical and quantum variations have a qualitatively similar behaviour. In both classi-
+cal and quantum case, we notice the presence of red wings at large oxygen-oxygen distances
+(dO1O2 ∈ [2.5, 2.7] ˚A), which are the signature of thermally activated Eigen-like states, with
+a strongly localised proton. This is related to less frequent elongated-Zundel configurations,
+indicated by the depleted distribution for dO1O2 < 2.5 ˚A, confirming that the distorted-Eigen
+configurations are indeed promoted by high temperature. For quantum nuclei, the correspond-
+ing depletion goes well below the elongated-Zundel region, by touching also short-Zundel con-
+figurations, down to dO1O2 ∼ 2.3 ˚A, at variance with the classical case, where the short-Zundel
+configurations are not involved.
+To interpret these results, we first construct an accurate effective potential by projecting
+the full PES, computed during QMC-driven classical MD calculations, onto the degrees of
+freedom mostly relevant to understand the dynamics of the hydrated proton. These are the
+dO1O2 distance and the proton sharing coordinate δ, referenced to the midpoint of the O1H+O2
+complex: δ ≡ ˜dO1/2H+ − dO1O2/2, with ˜dO1/2H+ the O1/2-H+ distance projected onto the O1O2
+direction. The resulting two-dimensional (2D) potential is V2D = V2D(dO1O2, δ). We refer the
+reader to Secs. S4 and S5 of the SI for technical details about the PES projection. We highlight
+that the potential V2D is derived here at VMC quality. We also notice that δ is the vibrational
+coordinate of the proton shuttling mode, while dO1O2 is related to the stretching mode of the two
+water molecules in the cluster core.
+Given V2D(dO1O2, δ), we then proceed to quantize the variable δ. Indeed, while dO1O2 can
+be taken as classical, for it is related to the motion of heavier oxygen atoms of mass mO, the
+δ coordinate must be quantised, owing to the light mass (mH) of the hydrated proton. At the
+leading order in 2mH/(mO + mH), we separate the stretching mode from the shuttling one,
+by invoking a Born-Oppenheimer type of approximation for the two species. We finally solve
+8
+
+quantum-mechanically the Hamiltonian of a proton in the potential Vδ ≡ V2D(α, δ)|α=dO1O2 at
+fixed dO1O2 value. In Fig. 4(a-c) we plot the ground state distribution and eigenvalues obtained
+for three distances, i.e. at dO1O2=2.375 ˚A, in the short-Zundel region close to the boundary
+between the short and the elongated Zundel, at dO1O2= 2.495 ˚A, in the elongated-Zundel region
+close to the frontier between the elongated Zundel and the distorted Eigen, and finally at dO1O2=
+2.585 ˚A, deep into the distorted Eigen regime.
+One can notice three different quantum behaviours of the vibrational shuttling mode, that
+provide a more quantitative ground to the three-regime distinction made at the beginning. In the
+short Zundel, Vδ is indeed a quadratic potential with a single minimum at the core center, which
+widens as dO1O2 gets close to dsymm ≃ 2.38 ˚A, a distance where it becomes quartic because
+its curvature changes sign. The ground state energy, i.e. the zero point energy (ZPE) of the
+shuttling mode, decreases as the potential widens, as reported in Fig. 4(d). In the elongated
+Zundel, a central barrier starts to develop, with a ground-state proton distribution that stays
+uni-modal thanks to a ZPE larger than its height, till dO1O2 ≃ 2.5 ˚A, where the ZPE equals
+the barrier height. In this regime, for dO1O2 ∈ [dsymm, 2.5 ˚A], the ZPE is particularly small, due
+to the quartic nature of Vδ, and weakly dO1O2-dependent, as shown in Fig. 4(d). Finally, for
+dO1O2 > 2.5 ˚A, we enter the distorted-Eigen regime, with an even larger central barrier (> 1000
+K), such that the quantum proton is instantaneously localised in one of the two wells, and its
+distribution is then bimodal. The ZPE starts to rise again as dO1O2 is stretched, with a slope
+steeper - in absolute value - than the ZPE decrease in the short Zundel, because it is now set by
+the much deeper lateral minima of the double-well potential. This can be seen again in Fig. 4(d).
+We can now correct the classical O1-O2 potential, defined as VO1O2 ≡ V2D(dO1O2, δ)|δ=δmin,
+where δmin is the V2D minimum at fixed dO1O2 value, by adding the ZPE ∀dO1O2, obtained from
+the quantisation of the shuttling mode δ. The resulting potential is plotted in Fig. 4(e). Amaz-
+ingly, the anharmonic classical VO1O2 potential becomes harmonic after ZPE-correction. It is
+9
+
+a consequence of the much larger ZPE in the distorted-Eigen configurations than in the short
+Zundel, which compensates for the underlying VO1O2 anharmonicity. This rationalises two main
+features. On the one hand, it explains the very low thermal expansion of ⟨dO1O2⟩, being the aver-
+age position in a harmonic potential temperature-independent. On the other hand, it proves that
+NQEs enhance the occurrence of short-Zundel configurations upon heating, while the distorted
+Eigen is penalised by its large ZPE with respect to the classical counterpart.
+Above RT, the distorted Eigen configurations will eventually become dominant again. This
+can be understood within this framework as well. Indeed, thermal excitations are energetically
+more available in the distorted Eigen, where the spacing between the ZPE and the first-excited
+state shrinks, and higher excited states are piled up more densely than in the short and elongated
+Zundel (see Fig. 4(a-c)).
+Optimal proton transfer from instantons statistics
+The analysis made so far highlights the
+paramount importance of the NQEs to set the non-trivial temperature behaviour of the H13O+
+6
+cluster. At this stage, direct information about the excess proton dynamics along the QMC-
+PIMD trajectory is necessary to estimate more quantitatively its impact on the PT processes
+occurring in the system.
+One way to achieve this goal is by analysing the statistics of selected transition-state (TS)
+configurations, defined by means of instanton theory. Within the PI formalism, the instanton
+path seamlessly connects the reactants and products minima, along the minimal action trajec-
+tory, periodic in the quantum imaginary time τ = βℏ[28]. It provides a generalisation of the TS
+theory for anharmonic quantum systems[29], and it has been very recently applied in a QMC
+framework [30, 31], by efficiently recovering the proper scaling of ground-state tunneling rates.
+TS configurations are therefore identified as those where each half of the instanton path is lo-
+cated on either side of the central O1O2 midpoint, sampled during the QMC-PIMD dynamics.
+10
+
+With the aim at resolving the contribution of the three different regimes to the PT dynamics,
+we collect the instanton events and compute their statistical distribution as a function of dO1O2.
+We plot the instanton density distribution function in Fig. 5(a) at various temperatures. To
+deepen our analysis, we compute also the cumulative density distribution function in Fig. 5(b),
+after normalising it based on the algorithmic frequency of the instanton occurrences, as counted
+during our QMC-PIMD simulations. Although this does not give direct access to real-time
+quantities, the ring-polymer MD with Langevin thermostat has been shown to yield physically
+reliable information on frequencies and frequency variations[32]. Note that the coupling with
+the Langevin thermostat is kept constant across the full temperature range analysed here[32].
+The fully integrated frequency distribution gives the total proton hopping frequency, plotted in
+Fig. 5(c) as a function of temperature. This shows a clear maximum located in the [250 − 300]
+K temperature range. Consequently, we expect the hydrated proton mobility to be optimal in
+a near-RT window, with a maximised Grotthus diffusion. To understand the source of this
+temperature “sweet spot”, in the same panel (c) we plot the contribution to the total frequency
+of instanton events occurring in the short-Zundel region. This is yielded by the cumulative
+frequency distribution of panel (b) evaluated at the boundaries between short and elongated
+Zundel, i.e. at dO1O2 = dsymm. The short-Zundel contribution to the total frequency shows
+a peak of the same intensity as the total one in the same temperature range, clearly pointing
+to the key role played by thermally activated short-Zundel configurations to the PT dynamics.
+The short-Zundel arrangement enables instantaneous proton jumps between the two sides of the
+cation, since there is no barrier to cross. Thus, the “sweet spot” constitutes the best compromise
+between acquiring enough thermal energy to access short-distance configurations, boosted by
+NQEs, and controlling the amplitude of the chemical (covalent or H-) bonds fluctuations, that
+might trap the proton into an asymmetric well. Indeed, at larger temperatures (> 300 K), the
+onset of distorted-Eigen and the corresponding fall of short-Zundel configurations localize the
+11
+
+hydrated proton around its closest oxygen atom, thus reducing its shuttling probability.
+Beside this PT mechanism, which is adiabatic in nature and driven by the synergy of ZPE
+and thermal effects, NQEs could also contribute to the proton diffusion by means of instanta-
+neous tunneling, which can further accelerate the PT dynamics. By computing the root-mean-
+square (RMS) displacement correlation functions[33] over the instantons population, we veri-
+fied that tunneling events could take place only in the distorted Eigen and in the intermediate
+temperature range (see Sec. S6 of SI for a detailed analysis). This additional PT channel has
+however a marginal effect with respect to the main mechanism unveiled here. Indeed, Fig. 5(c)
+shows that the “sweet spot” is mainly due to PT events originating in short-Zundel configura-
+tions, where quantum tunneling is not relevant.
+3
+Conclusions
+Using unprecedentedly accurate QMC-PIMD simulations of the H13O+
+6 cation at finite temper-
+ature, we found a remarkably low thermal expansion of the protonated water hexamer core. It
+stems from a cooperative action of both NQEs and thermal effects, which leads to the emer-
+gent behaviour of short-Zundel species as PT booster, where the excess proton is perfectly
+shared between two neighbouring water molecules. The relevance of short-Zundel configura-
+tions is enhanced by NQEs, which instead penalize the distorted-Eigen states, having a larger
+ZPE. In the intermediate temperature range, comprising RT, the occurrence of short-Zundel
+events is maximised by thermal population, leading to a “sweet spot” in the PT dynamics.
+Around these temperatures, distorted-Eigen states can still contribute to PT with quantum tun-
+neling processes, although occurring at much lower rates. The cluster core spreads out again at
+larger temperatures, as soon as stronger thermal fluctuations favor the formation of more clas-
+sical distorted-Eigen structures, where the proton gets strongly localised in one of the flanking
+molecules.
+12
+
+The short-Zundel quantum species is crucial for an efficient proton diffusion, as the short-
+ness of its structure enables a fast charge redistribution during the adiabatic PT process. Very
+recent progress in ultrafast broadband two-dimensional (2D) IR spectroscopy[34, 35] allowed
+to probe the vibrational properties of protonated water at vibrational frequencies around the hy-
+drated proton stretching mode, by measuring the lowest-lying excitations in the mid-infrared
+continuum[35].
+These state-of-the-art experiments revealed a strongly inhomogeneous be-
+haviour of the pump-probe spectra, implying large structural distributions in proton asymmetry
+and O1O2 distance. Therefore, the traditional “Zundel limit”[3] needs to be revisited and ex-
+tended, in order to cover the broad range of structures detected experimentally[36, 37]. In par-
+ticular, the occurrence of qualitatively different short hydrogen-bond configurations, straight-
+forwardly connected with the short-Zundel species described here, has been detected and high-
+lighted in a recent fully solvated (HF2)−(H2O)6 experiment through femtosecond 2D IR spec-
+troscopy in Ref. [38]. The present work crucially extends those findings by providing a temper-
+ature resolved analysis of the short hydrogen-bond events and by revealing their fundamental
+relation with the PT dynamics.
+While proton transfer and proton transport occur in a variety of environments, from so-
+lutions to membrane proteins and fuel-cell membranes, the protonated water hexamer is the
+smallest cluster to incorporate most of the PT experimental features and solvation effects at the
+leading order. Our findings thus call for further efforts to explore the temperature behaviour of
+the proton dynamics and transport both in aqueous systems and in other environments, more
+specifically for biological systems around life conditions.
+13
+
+4
+Methods
+4.1
+Zero-temperature electronic structure calculations
+Before running finite-temperature calculations, we build a quantum Monte Carlo (QMC) vari-
+ational wave function. The molecular dynamics (MD) will develop on the potential energy
+surface (PES) generated by the variational energy of this wave function. All zero- and finite-
+temperature calculations have been carried out with the TurboRVB code[39]. We choose the
+variational ansatz such that the chemical accuracy in the binding energy of the Zundel ion and
+water dimer is reached. We highlight the fact that benchmarking the binding energy is much
+stricter than taking energy differences of geometries around the minimum, because the config-
+urations involved in the binding energy are very different.
+The variational wave function |Ψq⟩ we used in our work is written as a Jastrow Antisym-
+metrised Geminal Power (JAGP) product[40]
+Ψq(x1, . . . , xNel) = Jq(r1, . . . , rNel)ΨAGP,q(x1, . . . , xNel).
+(1)
+The set {xi = (ri, σi)}i=1,...,Nel represents spatial and spin coordinates of the Nel electrons.
+The JAGP wave function has been described extensively described elsewhere[41, 42, 43,
+44]. Here, we report its main ingredients. The Bosonic Jastrow factor is written as a product of
+one-body, two-body and three/four-body terms Jq = J1,qJ2,qJ3,q. The one body term reads
+J1,q
+= exp
+�
+−
+Nel
+�
+i
+N�
+j
+(2Zj)3/4u
+�
+(2Zj)1/4|ri − qj|
+�
+�
+(2)
+with u(|r − q|) = 1−e−b|r−q|
+2b
+and b is a variational parameter, which satisfies the electron-ion
+Kato cusp conditions. N the number of atoms and Zj the electric charge of the j-th atom. In the
+protonated hexamer Hamiltonian, the hydrogen keeps the bare Coulomb potential, while for the
+oxygen atoms are replaced by the Burkatzki-Filippi-Dolg (BFD) pseudopotential[45], smooth
+at the electron-ion coalescence points. Thus, J1,q is applied only to the hydrogen atom. The
+14
+
+two-body correlations are dealt with by the higher-order Jastrow factors. The two-body Jastrow
+factor is defined as
+J2,q = exp
+� Nel
+�
+i<j
+u(|ri − rj|)
+�
+,
+(3)
+where u is a function of the same form as in Eq. (2), but with a different variational parameter.
+The three-four body Jastrow factor is
+J3,q = exp
+� Nel
+�
+i<j
+ΦJq(ri, rj)
+�
+,
+(4)
+with
+ΦJq(ri, rj) =
+N
+�
+a,b
+NJ
+basis
+�
+µ,ν
+ga,b
+µ,νΨJ
+a,µ(ri − qa)ΨJ
+b,ν(rj − qb),
+(5)
+where N J
+basis is the number of the basis set functions ΨJ
+a,µ. We used optimally contracted gemi-
+nal embedded orbitals (GEOs)[46] as basis set, expanded over a primitive O(3s,2p,1d) H(2s,1p)
+Gaussian basis. The convergence study of the water dimer binding energy as a function of the
+Jastrow GEO expansion is reported in Sec. S1.1 of the SI.
+The Fermionic part of the wave function is expressed as an antisymmetrised product of the
+spin singlet geminals or pairing (AGP) functions Φq(xi, xj):
+ΨAGP,q(x1, . . . , xNel) = ˆA [Φq(x1, x2), . . . , Φq(xNel−1, xNel)] .
+(6)
+The spatial part φq(ri, rj) of the spin singlets Φq(xi, xj) is expanded over N AGP
+basis optimally
+contracted GEOs, such that
+φq(ri, rj) =
+N
+�
+a,b
+NAGP
+basis
+�
+µ,ν
+λa,b
+µ,ν ¯ΨAGP
+a,µ (ri − qa)¯ΨAGP
+b,ν
+(rj − qb).
+(7)
+The AGP GEOs are linear combination of primitive O(5s5p2d) H(4s2p) Gaussian basis func-
+tions. We highlight that the Fermionic part is fully optimised at the QMC level for each MD
+step, and not generated by on-the-fly DFT calculations.
+15
+
+The GEOs are very effective in reducing the total number of variational parameters, by
+keeping a high level of accuracy. This makes the wave function optimisation[47, 40, 48] much
+more efficient. Dealing with a compact wave function is very important, if one wants to use it
+as variational ansatz in a MD simulation, because in a MD framework the wave function needs
+to be optimised at every MD iteration. Indeed, the wave function optimisation is by far the most
+time consuming step of our QMC-driven MD approach.
+Previous works on the Zundel ion[44, 18] found that the optimal balance between accuracy
+and computational cost for the determinantal part is reached by the O[8]H[2] contracted GEO
+basis, in self-explaining notations. As the protonated water hexamer is a very similar system,
+in this work we used the same O[8]H[2] GEO contraction for the AGP part. Moreover, we
+further simplified the variational wave function previously developed for the Zundel ion, by
+contracting also the Jastrow basis set, using the same GEO embedding scheme. We found that
+the O[6]H[2] GEO basis set for the Jastrow factor is a very good compromise between accuracy
+and number of parameters, as we checked in the water dimer (see Sec. S1.1 of the SI). The
+final accuracy is about 1 kcal/mol in the dissociation energy of the water dimer, and supposedly
+it is much higher around the stable geometries of water clusters. Thus, we used the O[6]H[2]
+GEO basis set for the Jastrow factor, and the O[8]H[2] GEO basis for the AGP part in all our
+subsequent MD simulations. For the protonated water hexamer, this results into a total number
+of 6418 variational parameters, comprising ga,b
+µ,ν in Eq. 5, λa,b
+µ,ν in Eq. 7, the parameters of the
+homogeneous one-body (Eq. 2) and two-body (Eq. 3) Jastrow factors, and the linear coefficients
+of the Jastrow and determinantal basis sets.
+16
+
+4.2
+Finite-temperature calculations
+4.2.1
+Path Integral Langevin Dynamics
+At finite temperature, we carried out path integral Langevin dynamics simulations to include
+NQEs. To do so, we used the recently developed algorithm published in Ref. [18], which com-
+bines a path integral approach with very accurate Born-Oppenheimer (BO) forces computed by
+QMC. It is an efficient approach, alternative to the coupled electron ion Monte Carlo (CEIMC)
+developed by Ceperley and coworkers[49, 50, 51]. The intrinsic noise of the QMC force esti-
+mator is treated by the noise correction scheme developed in Refs. [17, 52, 18], which is based
+on the fulfilment of the fluctuation-dissipation theorem. This implies that the friction matrix γ
+governing the dumped dynamics is related to the random force η via the α matrix:
+α (q)
+=
+2kBTγ (q) ,
+(8)
+⟨ηi (t) ηj (t′)⟩
+=
+αi,j (q) δ (t − t′) ,
+(9)
+with q the vector of nuclear coordinates. The q-dependence comes from the QMC noise cor-
+rection, implemented through the relations:
+α (q)
+=
+γBO/(2kBT) + ∆0αQMC (q)
+(10)
+α
+QMC
+i,j (q)
+=
+⟨(fi (q) − ⟨fi (q)⟩)⟩ ⟨(fj (q) − ⟨fj (q)⟩)⟩ ,
+(11)
+where αQMC in Eq. 11 is the covariance matrix of QMC ionic forces, measuring their stochastic
+fluctuations, and γBO and ∆0 parameters taking values for an optimal Langevin dynamics. The
+random force η is then used to thermalise the system to a target temperature, according to the
+Langevin thermostat of Eq. 8.
+The quantum particles are described by necklaces extended in the imaginary time interval
+[0, ℏβ], with β = 1/(kBT), following the quantum-to-classical isomorphism. This imaginary
+time interval is divided into M slices, the so-called “beads”, leading to an effective classical
+17
+
+system of NM particles. The path integral Langevin dynamics we developed in Ref. [18] is
+very efficient, because the quantum harmonic forces and the Langevin thermostat - thermalising
+the quantum degrees of freedom - are evolved together by means of an exact propagator, without
+Trotter breakup. The evolution of quantum particles in a thermal bath `a la Langevin represents a
+quantum Ornstein-Uhlenbeck dynamics. Therefore, we dubbed our integration scheme as “path
+integral Ornstein Uhlenbeck dynamics (PIOUD)”. The algorithm is detailed in Ref. [18].
+In order to evolve the system and to sample the thermal quantum partition function, nuclear
+forces must be estimated at each iteration by computing the gradients f = −∇qV (q). The
+potential energy surface V (q) is evaluated by VMC, namely:
+V (q) = ⟨Ψq|H(q)|Ψq⟩
+⟨Ψq|Ψq⟩
+,
+(12)
+where |Ψq⟩ is the QMC wave function, which minimizes the expectation value of H(q) for
+each bead configuration q(k), according to the Born-Oppenheimer approximation.
+The electronic variational wave function depends on the coordinates q(k) of the k-th bead
+in two ways. Directly, through the explicit dependence on the ion positions provided by the lo-
+calised basis set, and in an indirect way, through the wave function parameters optimised at each
+q(k), in compliance with the Born-Oppenheimer approximation. While the former dependence
+is of leading order, the latter can be neglected in a first approximation. A clever way to do so
+is to average the optimal parameters across different beads, by gaining a significant fraction of
+statistics in the QMC energy minimisation. More precisely, the beads are gathered in groups of
+Ngroups members each, to share the same set of wave function parameters. This is called “bead
+grouping approximation”, and it has been introduced in Ref. [18].
+Once the number of groups Ngroups is set for the beads, the electronic wave function is op-
+timised at each new ionic position generated by the dynamics. This is done by energy minimi-
+sation via the most advanced optimisation techniques[42, 48]. Between two consecutive steps
+18
+
+of ion dynamics, one needs to perform Nopt steps of energy minimisation, in an iterative fash-
+ion. Nopt must be large enough to converge the wave function for each new ionic configuration.
+Thus, this parameter is tuned such that the BO approximation is fulfilled, and the dynamics
+follows the correct PES along the PIOUD trajectories.
+During the dynamics, the GTO exponents in both the Jastrow and the AGP part of the
+wave function are kept frozen to make the simulation stable. Due to the continuity of the
+nuclear trajectories, the number of energy minimisation steps is significantly smaller than the
+one required for a wave function optimisation from scratch.
+There is a set of sensitive parameters one needs to tune to have stable and unbiased simula-
+tions. They are:
+(i) Convergence for quantum effects set by M. In our calculations, we used M= 32 for
+T= 300 − 400 K and M= 64 for T= 200 K. The bead grouping approximation is made
+with Ngroup = 1. Therefore the whole ring shares the same wave function parameters,
+except for the nuclear coordinates;
+(ii) Time step δt for the integration of the equations of motion. We used δt = 1 fs for a
+controlled time integration error, yielding a difference between the virial and primitive
+estimators of the quantum kinetic energy below a 25 mHa threshold along all the trajec-
+tories;
+(iii) A stable target temperature is reached despite the QMC noise by setting the parameters
+γBO and ∆0, defining the α matrix in Eq. 10. We used γBO = 0 and ∆0 = 0.5 δt,
+optimal values for other similar systems, such as the Zundel ion[18]. Indeed, the simu-
+lation is efficient when the damping in the BO sector is minimised. The thermalisation
+of the system is guaranteed thanks to the optimal damping condition[53] applied to the
+internal modes of the ring-polymer, with the damping parameter of the center-of-mass
+19
+
+translational modes set to 0.231 fs−1;
+(iv) To enforce the fulfilment of the BO approximation, we allowed for Nopt = 5 iterative
+wave function optimisation steps at each MD iteration, such that the electronic energy
+minimum is reached within the statistical accuracy for every ionic configuration, and the
+PES is sampled without stochastic bias.
+4.2.2
+Classical Langevin Dynamics
+For classical MD calculations, we used an improved variant of the original algorithm developed
+by Attaccalite and Sorella[17]. This variant has been detailed in Refs. [52, 18]. It includes a
+better integration scheme, involving a Langevin noise touching both coordinates and momenta,
+which are therefore correlated.
+As in the PIOUD calculations, relevant parameters are the time step δt = 1 fs, the QMC
+noise correction parameters γBO = 0.2 fs−1 and ∆0 = δt, and the number of QMC optimisation
+steps per nuclear iteration Nopt = 5.
+Acknowledgments
+FM, RV, AMS and MC acknowledge Dominik Marx for useful discussions. MP, RV, AMS and MC
+thank the CNRS for the 80PRIME doctoral grant allocation. FM and MC acknowledge computational
+resources provided by the PRACE projects number 2016133322 and 2017153936. MC thanks GENCI
+for providing computational resources at TGCC and IDRIS under the grant number 0906493, and the
+Grands Challenges DARI for allowing calculations on the Joliot-Curie Rome HPC cluster under the
+project number gch0420. TM and MC are grateful to the European Centre of Excellence in Exascale
+Computing TREX-Targeting Real Chemical Accuracy at the Exascale, which partially supported this
+work. This project has received funding from the European Unions Horizon 2020 Research and Innova-
+tion program under Grant Agreement No. 952165.
+20
+
+short Zundel
+elongated Zundel
+distorted Eigen
+Figure 1: Different regimes of the protonated water hexamer H13O+
+6 . Left panel: short-Zundel
+configuration with a Zundel center (H5O+
+2 ) in colors and its first solvation shell (4 H2O) in
+gray shades. Central panel: elongated Zundel with the quantum nature of hydrogen atoms
+highlighted by the full representation of its imaginary-time positions in a PI configuration. Right
+panel: distorted-Eigen configuration with an Eigen cation (H9O+
+4 ) in colors accompanied by
+two solvating water molecules (2 H2O) in gray shades. The O1, O2 and H+ labels are used
+throughout the paper to refer to the corresponding atoms, as indicated here.
+21
+
+HH+H
+02a) classical
+b) quantum
+c)
+Figure 2:
+Classical (panel a)) and quantum (panel b)) oxygen-oxygen gO1O2 pair correlation
+functions of the H13O+
+6 ion as a function of temperature. The dashed vertical lines indicate
+the average ⟨dO1O2⟩ distance for each simulation, at the corresponding temperature. The dotted
+vertical line is located at the classical equilibrium geometry. Panel c) shows the T-dependence
+of the ⟨dO1O2⟩ average distance. The classical equilibrium geometry is represented by a short-
+dashed horizontal black line. At 250 K and 300 K the oxygen-oxygen distance is shortened by
+NQEs with respect to the classical counterpart.
+22
+
+2.48
+classical
+quantum
+2.46
+A
+2.44
+2.42
+O,02 a
+2.40
+2.38
+0
+50
+100 150 200 250 300 350 400
+T (K)100K
+0.18
++++++
+200K
+0.16
+250K
+0.14
+300K
+0.12
+350K
+0.10
+0.08
+0.06
+0.04
+0.02
+0.18
+0.16
+0.14
+0.12
+0.10
+0.08
+0.06
+0.04
+0.02
+2.25 2.3 2.35 2.4 2.45
+2.52.55
+2.6
+O,O2 distance (A)Classical particles
+Quantum particles
+Short 
+Zundel
+Elongated
+Zundel
+Distorted
+Eigen
+Short 
+Zundel
+Elongated
+Zundel
+Distorted
+Eigen
+Figure 3: Difference between bidimensional oxygen-oxygen/oxygen-proton distributions ρ2D
+obtained by QMC-driven LD simulations for classical (left panels) and quantum (right panels)
+particles, computed at different temperatures. The bidimensional distribution computed at 250
+K is taken as reference. Positive (negative) regions are in red (blue) color. The black filled
+circles correspond to the zero-temperature equilibrium geometries of the H13O+
+6 ion at a fixed
+dO1O2 distance. The coloured background highlights the three different regimes explained in the
+paper: the short Zundel (gray), the elongated Zundel (yellow), and the distorted Eigen (green)
+species.
+23
+
+d)
+e)
+Short 
+Zundel
+Elongated
+Zundel
+Distorted
+Eigen
+Figure 4: NQEs on the shuttling mode, and their impact on the O1-O2 interatomic potential
+VO1O2. We quantize the proton shuttling mode δ, defined as the displacement along the segment
+connecting the two oxygen atoms in the core of the cluster from its mid-point position. We
+study the ground-state wave function and the first 5 eigenvalues for the confining potential Vδ,
+as a function of dO1O2. Panels a), b) and c) report the ground state wave function and the lowest
+5 energy levels for dO1O2= 2.375, 2.495 and 2.585 ˚A, respectively. In panel d), the variation of
+the zero-point (ground-state) energy (ZPE) as a function of dO1O2 is explicitly plotted. While
+the ZPE dependence is very flat in the elongated-Zundel region (depicted by the yellow shaded
+area), the ZPE increases in both short-Zundel (gray shaded area) and distorted-Eigen (green
+shaded area) regions, with a much steeper slope in the latter. In panel e), the ZPE is added to the
+classical interatomic potential VO1O2 (solid blue line) to yield the quantum-corrected effective
+interatomic potential (solid dark-pink line) between the two inner oxygen atoms.
+24
+
+quantuminteratomicpotential
+classical interatomic potential
+2000
+1500
+>
+1000
+500
+0
+2.25
+2.3
+2.35
+2.4
+2.45
+2.5
+2.55
+2.6
+2.65
+do,O,
+(A)ZPE of shuttling mode
+2000
+1500
+ZPE (K)
+1000
+500
+0guantum interatomic potential
+classical interatomic potential
+2000
+1500
+Vo,02
+1000
+500
+0
+2.25
+2.3
+2.35
+2.4
+2.45
+2.5
+2.55
+2.6
+2.655th energy level
+4th energy level
+a)
+3rd energy level
+8000
+1st energy level
+confining potential
+6000
+ground state
+do,O, = 2.375 A
+4000
+2000
+0
+b)
+8000
+6000
+do,O, = 2.495 A
+S
+¥4000
+V
+2000
+0
+c)
+8000
+6000
+= 2.585 A
+4000
+2000
+0
+-0.6
+-0.4
+-0.2
+0.2
+0.4
+0.6
+0
+shuttling displacement  (A)a)
+b)
+c)
+Figure 5: a) Instanton distribution resolved as a function of the dO1O2 distance for different
+temperatures. b) Cumulative distribution of a) normalised by the occurrence frequency of the
+instanton (proton hopping) events during the PIMD simulations. c) Proton hopping frequency
+as a function of temperature, together with the contribution coming from the short Zundel con-
+figurations, with dO1O2 < dsymm = 2.38 ˚A. The dsymm value is reported as vertical dashed line in
+panels a) and b). Here, we report simulations performed also at 400 K, a temperature at which
+the cluster is still stable or meta-stable.
+25
+
+0.025
+full contribution
+short Zundel events
+proton hopping frequency (1/fs)
+0.020
+0.015
+0.010
+0.005
+0.000
+0
+50
+100 150 200 250 300 350 400
+T (K)50 K
+20
+IIIIII
+100 K
+150 K
+instanton distr (1/A)
+200 K
+15
+250 K
+300 K
+350 K
+10
+5
+cumulative frequency distr (1/fs)
+0.02
+0.01
+0.00
+2.25
+2.3
+2.35
+2.4
+2.45
+2.5
+2.55
+O,O distance (
+(A)Supplementary information
+S1
+Zero-temperature electronic structure calculations
+S1.1
+Preparation and optimisation of quantum Monte Carlo (QMC) wave
+function
+As described in the Methods Section, before running finite-temperature calculations, we opti-
+mize a QMC variational wave function |Ψq⟩ at zero temperature, written as a Jastrow Antisym-
+metrised Geminal Power (JAGP) ansatz[40]. During the finite-temperature molecular dynam-
+ics, energy and forces are computed at the variational Monte Carlo (VMC) level, based on the
+variational optimisation of the QMC wave function. Both Jastrow and AGP expansions are de-
+veloped over a primitive O(3s2p1d) H(2s1p) and O(5s5p2d) H(4s2p) Gaussian basis functions,
+respectively. The primitive basis sets are then contracted using the geminal embedded orbitals
+(GEOs) scheme[46].
+Previous works on the Zundel ion[44, 18] found that the optimal balance between accuracy
+and computational cost for the determinantal part is reached by the O[8]H[2] contracted GEO
+basis, in self-explaining notations. As the protonated water hexamer is a very similar system, in
+this work we used the same O[8]H[2] GEO contraction for the AGP part. Moreover, we further
+simplified the variational wave function previously developed for the Zundel ion, by contract-
+ing also the Jastrow basis set, using the same GEO embedding scheme. We tried different
+contraction sets, and tested them on the water dimer dissociation energy curve, as reported in
+Fig S1. The water dimer is a stringent benchmark for the quality of our wave function, as it has
+a chemical complexity similar to the Zundel ion, with the main difference of being charge neu-
+tral. Charge neutrality allows us to directly probe the Jastrow capability of controlling charge
+fluctuations in the system, a fundamental property when coupled with the AGP determinantal
+part[54].
+S1
+
+Figure S1: Water dimer dissociation energy curve as a function of the oxygen-oxygen distance
+obtained by VMC, using different contracted basis sets in the Jastrow factor of a Jastrow-Slater
+wave function. Each trial wave function is built using the same basis set for the determinantal
+part, which is optimised together with the various Jastrow factors tested here. The black curve
+indicates the reference CCSD(T) result.
+As shown in Fig. S1, we find a systematic improvement as the number of GEOs orbitals
+increases, with the O[6]H[2] set yielding energies very close to the Jastrow primitive basis set
+reference at all oxygen-oxygen distances. As reported in Tab. S1, this is obtained with a number
+p of variational parameters significantly smaller than the one of the primitive basis set expan-
+sion. Thus, we used the O[6]H[2] GEO basis set for the Jastrow factor, and the O[8]H[2] GEO
+basis for the AGP part in all our subsequent molecular dynamics (MD) simulations. For the
+protonated water hexamer, this results into a total number of 6418 variational parameters, com-
+prising ga,b
+µ,ν, λa,b
+µ,ν, the parameters of the homogeneous one-body and two-body Jastrow factors,
+and the linear coefficients of the Jastrow and determinantal basis sets (see Methods Section for
+a detailed description of the wave function parameters).
+S2
+
+0
+-1
+*F
+Binding energy (kcal/mol)
+5.4
+5.2
+-2
+(kcaVmol)
+5
+4.8
+4.6
+4.4
+3
+4.2
+4
+T
+3.8
+T
+Level of theory
+Primitive Jastrow
+HH
+O[41Hr11 Jastrow
+O[6iH[1i Jastrow
+-5
+O[6]H[2] Jastrow
+E
+CCSD(T) from B3LYP
+3
+4
+5
+6
+7
+8
+Distance between oxygens (A)Basis set
+p
+Ebind (kcal/mol)
+Primitive Jastrow and primitive determinant
+6303
+4.46(8)
+Primitive Jastrow and O[8]H[2] GEO determinant
+2089
+4.40(8)
+O[6]H[2] GEO Jastrow and O[8]H[2] GEO determinant
+1283
+4.26(8)
+Table S1:
+Water dimer binding energies for QMC variational wave functions obtained with
+different types of basis set contractions. The corresponding number p of variational parameters
+is also reported.
+A more extended description of the variational wave function can be found in Ref. [44].
+S1.2
+Comparison between QMC and other electronic structure methods
+To probe the microscopic rearrangement which triggers proton transfer (PT) processes in the
+protonated water hexamer at finite temperature, it is necessary to determine the potential energy
+surface (PES), in particular around the equilibrium geometry of the cluster. At variance with the
+Zundel cation, the protonated hexamer minimum energy configuration is asymmetric, implying
+that the hydrated proton is not equally shared between the two central water molecules.
+In Fig. S2, we report the equilibrium position of the hydrated proton H+ - expressed as
+distance dH+O1 (dH+O2) from the flanking oxygen atom O1 (O2) - as a function of the distance
+dO1O2 between the two central oxygen atoms. Fig. S2 shows the equilibrium geometries at
+constrained dO1O2 obtained by various methods: density functional theory (DFT) with the PBE
+functional (dark green), DFT modified to include dispersive van der Waals (vdW) interactions
+in the DF2 implementation[55] (magenta), variational Monte Carlo (blue circles) and Møller-
+Plesset (MP2) (red triangles). The dO1O2 distance corresponding to the global minimum is
+indicated by a vertical dashed line for each method.
+The PBE functional predicts a short-Zundel-like symmetric global minimum, which is erro-
+neous. More generally, this functional gives a poor description of the proton location when one
+stretches the dO1O2 distance. After inclusion of dispersion effects in the DF2 functional, the ge-
+ometric properties of the system are significantly improved, displaying a better agreement with
+S3
+
+Figure S2:
+Equilibrium position of the excess proton H - expressed as distance dHO1 (dHO2)
+from the flanking oxygen atom O1 (O2) - as a function of the separation dO1O2 between the
+two central oxygen atoms, reported for different computational methods. Vertical dashed lines
+indicate the equilibrium dO1O2 for each method.
+both QMC and MP2. Nevertheless, the predicted equilibrium dO1O2 is too large, which leads
+to an overly asymmetric cluster. Therefore, we expect the DF2 static barriers to be inaccurate,
+which is problematic in the perspective of studying PT at finite temperature by this method.
+Instead, MP2 and QMC are in excellent agreement, especially around dO1O2 = 2.4 ˚A.
+In Tab. S2 we report the equilibrium geometries yielded by PBE, DF2, MP2 and VMC,
+by showing the relevant distances involving the Zundel core of the protonated water hexamer.
+The VMC minimum geometry is in a very good agreement with the MP2 one, with an accurate
+description of the excess proton localisation, as previously seen in Fig. S2. The largest discrep-
+ancy between VMC and MP2 is for the OH intramolecular distances, which are slightly shorter
+in VMC. However, the overall evolution of equilibrium position of the hydrated proton H+ as
+S4
+
+1.9
+PBE-DFT
+DF2-DFT
+1.8
+QMC
+dH02
+MP2
+1.7
+1.6
+1.5
+1.4
+dHo1
+dH02
+1.3
+1.2
+do102
+1.1
+dH01
+1
+2.1
+2.2
+2.3
+2.4
+2.5
+2.6
+2.7
+2.8
+2.9a function of the oxygen-oxygen distance predicted by QMC follows well the one obtained by
+MP2, as one can see from Fig. S2.
+Theory
+O1O2
+O1H+
+H+O2
+O1H1
+O1H2
+O2H3
+O2H4
+DFT-PBE
+2.4156
+1.2078
+1.2078
+0.9935
+0.9935
+0.9935
+0.9935
+DFT-DF2
+2.4541
+1.1196
+1.3346
+0.9913
+0.9911
+0.9797
+0.9797
+MP2
+2.3867
+1.1690
+1.2188
+0.9877
+0.9878
+0.9847
+0.9848
+VMC
+2.3930(5)
+1.1555(5)
+1.2375(5)
+0.9800(8)
+0.9798(8)
+0.9752(8)
+0.9748(8)
+Table S2: Geometric properties (distances in ˚A) of the core of the protonated water hexamer
+minimum. Comparison between different computational methods.
+Due to the central distorted H-bond, the hydrated proton motion from one flanking water
+molecule to another is conditioned by the necessary energy it should acquire to go across the
+PT static barrier. This quantity is defined as the energy difference between the equilibrium
+structure (asymmetric) and the symmetrised one, where the proton is located at the mid-point
+of the considered dO1O2 distance. PT static barriers have been estimated at dO1O2 = 2.45 ˚A and
+2.5 ˚A. The barriers, converted into effective temperatures, are reported in Tab. S3 for different
+levels of theory.
+dO1O2 ( ˚A)
+2.45 ˚A
+2.50 ˚A
+DFT-DF2
+39
+483
+CCSD(T)
+141
+431
+MP2
+85
+327
+VMC
+195 ± 25
+562 ± 27
+Table S3:
+Static symmetrisation barriers (in Kelvin) of the H13O+
+6 cation at different dO1O2
+distances for various computational methods.
+DFT-DF2 seems unable to predict accurate PT barriers due to the misplacement of the global
+energy minimum. This further motivates the use of correlated methods to describe the electronic
+PES, such as coupled cluster CCSD(T) and MP2 theories. Their values are closer to the barriers
+predicted by VMC. They differ between each other by 0.1-0.2 kcal/mol, a difference within
+S5
+
+chemical accuracy. However, the QMC method exhibits a milder scaling with the system size.
+Therefore, the QMC approach is certainly the best candidate to perform fully ab initio MD
+simulations of small protonated water clusters at an affordable computational cost.
+S2
+Finite-temperature calculations: QMC-driven classical and
+quantum Langevin dynamics
+We simulated the protonated water hexamer by treating the electrons at the VMC level (JAGP
+wave function) and the nuclei considered as quantum particles as well, within a path integral
+(PI) formalism. To understand the impact of quantum effects, simulations with classical nuclei
+have also been performed. The Langevin dynamics (LD) algorithms used have been described
+in the Methods Section.
+In Tab. S4, we report the list of VMC+PILD simulations done. For their importance, par-
+ticularly long simulations are performed for the quantum case at temperatures of 50, 100, 200,
+and 300 K.
+Table S4: Summary of the simulations carried out in this work. In both classical and quantum
+calculations, a time step δt of 1 ft is used for all temperatures.
+quantum simulations
+classical simulations
+T(K)
+Nbeads
+Niterations
+Niterations
+50
+128
+35282
+-
+100
+128
+52184
+21454
+150
+64
+11218
+-
+200
+64
+32553
+20478
+250
+32
+23912
+24154
+300
+32
+31929
+22656
+350
+32
+18489
+26481
+400
+32
+23026
+27517
+S6
+
+S3
+Structural properties of protonated water clusters
+S3.1
+Role of solvation: Zundel ion versus protonated water hexamer
+As mentioned in the main text of the paper, the protonated water hexamer is the smallest water
+cluster including the full first-solvation shell, due to the presence of a Zundel core surrounded
+by 4 solvating H2O molecules. To quantify the impact of the solvation shell on the Zundel
+core, we compare in Fig. S3 the O1-O2 potential, VO1O2 (left), and the corresponding classical
+equilibrium geometry (right) of the two clusters at various dO1O2 (distance between the 2 central
+oxygen atoms). At short dO1O2, the slope of the protonated hexamer VO1O2 is slightly larger than
+the Zundel one, due to a greater electrostatic repulsion because of steric hindrance. At large
+dO1O2, the protonated hexamer PES is softer than the Zundel one, because the solvating H2O
+molecules enhance the polarisability of the core atoms. As explained in the paper, the balance
+between short- and long-range repulsion, once supplemented with the zero-point energie (ZPE),
+is key to quantify the relative abundance of short-Zundel and distorted-Eigen configurations,
+and thus, it allows for a quantitative understanding of the PT mechanism.
+We also find the H13O+
+6 equilibrium dO1O2, represented by a vertical dashed line in Fig. S3,
+to be ∼ 0.05 ˚A larger than the H5O+
+2 one. More importantly, at variance with the Zundel cation
+which is centrosymmetric, the protonated water hexamer equilibrium geometry is asymmetric
+with classical ions. This fundamental symmetry modification of the PES is induced by solvation
+effects, which tend to stabilize the hexamer into its elongated-Zundel configuration. This can
+rationalise some THz/FTIR absorption spectroscopy fingerprints of the solvated proton[56],
+which have been related to a fast inter-conversion between the (distorted-)Eigen and (short-
+)Zundel forms.
+Furthermore, it is noteworthy that at fixed dO1O2, the predicted barriers are larger in H13O+
+6
+(Tab. S3) than in the Zundel cation[44]. This is clearly due to the additional price that must be
+S7
+
+Figure S3:
+Comparison of the protonated water dimer and hexamer VO1O2 potential (left)
+and equilibrium geometry (right) as a function of the (central) oxygen-oxygen distance dO1O2.
+Vertical dashed lines indicate the corresponding equilibrium dO1O2. Notice that VMC and lattice
+regularised diffusion Monte Carlo (LRDMC)[41] energies are in nice statistical agreement for
+dO1O2 ∈ [2.3, 2.6] ˚A, the phase-space range explored by our MD simulations.
+paid for the rearrangement of the molecules in the solvation shell during the PT process.
+S3.2
+H13O+
+6 bidimensional distribution functions
+We report some finite-temperature properties of the H13O+
+6 system, studied by looking at the
+bidimensional distributions functions ρ2D, which correlate the distance between the central pro-
+ton and the neighbouring oxygen atoms (dH+O1, dH+O2) with dO1O2. They are shown in Figs. S4
+and S5, for quantum and classical simulations, respectively.
+S8
+
+12
+Zundel VMC
+Zundel LRDMC
+HexamerVMC
+Hexamer LRDMC
+8
+Energy [Kcal/mol]
+0
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, [A]1.7
+Zundel VMC
+Hexamer VMC
+1.6
+1.5
+A
+1.4
+dH+O1/2
+1.3
+1.2
+1.1
+1
+2.2
+2.3
+2.4
+2.5
+2.6
+do.02Figure S4: ρ2D computed from VMC-PIMD simulations at different temperatures.
+S9
+
+p100k
+1.6
+1.5
+1/A2
+30.0
+1.4
+25.0
+1.3
+20.0
+1.2
+15.0
+1.1
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O2 (A)P200K
+1.6
+1.5
+1/A2
+30.0
+1.4
+25.0
+1.3
+20.0
+1.2
+15.0
+1.1
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O2 (A)P250K
+1.6
+1.5
+1/A2
+30.0
+1.4
+25.0
+1.3
+20.0
+1.2
+15.0
+1.1
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O2 (A)P300k
+1.6
+1.5
+1/A2
+30.0
+1.4
+25.0
+1.3
+20.0
+1.2
+15.0
+1.1
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O2 (A)P350k
+1.6
+1.5
+1/A2
+30.0
+1.4
+25.0
+1.3
+20.0
+1.2
+15.0
+1.1
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, (A)Figure S5: ρ2D computed from VMC-MD simulations, with classical nuclei, at different tem-
+peratures.
+The difference between quantum and classical distributions is striking. The impact of nu-
+clear quantum effects (NQEs) on the temperature-dependence of H13O+
+6 structural properties
+S10
+
+p100k
+1.6
+1.5
+1/A2
+45.0
+1.4
+40.0
+35.0
+1.3
+30.0
+25.0
+1.2
+20.0
+1.1
+15.0
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, (A)P200K
+1.6
+1.5
+1/A2
+45.0
+1.4
+40.0
+35.0
+1.3
+30.0
+25.0
+1.2
+20.0
+1.1
+15.0
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, (A)P250K
+1.6
+1.5
+1/A2
+45.0
+1.4
+40.0
+35.0
+1.3
+30.0
+25.0
+1.2
+20.0
+1.1
+15.0
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, (A)P300K
+1.6
+1.5
+1/A2
+45.0
+1.4
+40.0
+35.0
+1.3
+30.0
+25.0
+1.2
+20.0
+1.1
+15.0
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, (A)P350K
+1.6
+1.5
+1/A2
+45.0
+1.4
+40.0
+35.0
+1.3
+30.0
+25.0
+1.2
+20.0
+1.1
+15.0
+10.0
+1.0
+5.0
+0.9
+0.0
+0.8
+2.2
+2.3
+2.4
+2.5
+2.6
+do,O, (A)and PT mechanism are analysed and detailed in the main text, based on the proton density
+distributions shown in Figs. S4 and S5.
+S4
+Towards an accurate modeling of the potential energy sur-
+face (PES)
+We exploit the calculation of VMC forces not only to perform QMC-driven classical and quan-
+tum LD, but also to extract the best PES fitting functional form for the excess proton and for
+the water-water interaction in the Zundel core. The final goal is to derive the two-dimensional
+(2D) model potential V2D = V2D(dO1O2, δ), where dO1O2 is the distance between the two central
+oxygen atoms and δ is the proton sharing coordinate, referenced to the midpoint of the O1H+O2
+complex: δ ≡ ˜dO1/2H+−dO1O2/2, with ˜dO1/2H+ the O1/2-H+ distance projected onto the O1O2 di-
+rection. The projection of the full interatomic potential on the restricted 2D manifold is done by
+integrating the other degrees of freedom over the thermal partition function, sampled during the
+MD dynamics, i.e. V2D(dO1O2, δ) ≡ ⟨V (q1, q2, qN−2)δ(q1 − dO1O2)δ(q2 − δ)⟩, where ⟨. . .⟩ is the
+average over the partition function of the classical/quantum statistical ensemble at fixed temper-
+ature, and V is the 3N-dimensional potential depending on the generalised nuclear coordinates
+of the full system. Analogously, one can define the one-dimensional (1D) potential acting be-
+tween O1 and O2 as V1D = V1D(dO1O2) ≡ ⟨V (q1, q2, qN−2)δ(q1 −dO1O2)⟩, according to previous
+notations. Derivatives of the previous potentials with respect to dO1O2 and/or δ can be defined
+in the same way. For instance, ∂V2D/∂δ ≡ ⟨∂V (q1, q2, qN−2)/∂q2 δ(q1 − dO1O2)δ(q2 − δ)⟩, and
+∂V1D/∂dO1O2 ≡ ⟨∂V (q1, q2, qN−2)/∂q1 δ(q1 − dO1O2)⟩.
+Given these definitions, we can proceed with the calculations of the corresponding quantities
+with the aim at modeling the potentials V1D and V2D. To do so, we will integrate the other degrees
+of freedom using the classical Boltzmann distribution in ⟨. . .⟩, as generated by the QMC-driven
+classical Langevin dynamics at 100, 250 and 350 K. Employing the classical partition function
+S11
+
+has the advantage that the potentials sampled in this way will tend to the original PES of the
+system as β → ∞, while the quantum partition function will lead to averaged potentials biased
+by quantum fluctuations even in the zero temperature limit. To compute these quantities from
+an MD sampling, the δ-functions in their definitions above are replaced by bins, whose size is
+given by the spacing between neighbouring points.
+In Fig. S6, we study the V1D(dO1O2) potential depending on the water-water distance dO1O2
+(left column), and its derivative ∂V1D/∂dO1O2 (right column). As one can see, the energy profile,
+at the left-hand side, is much more noisy than the behavior of its gradient, from where we
+can extract a precise value of the equilibrium dO1O2 distance, and the evolution of the potential
+around the minimum. This shows the advantage of computing QMC forces in order to determine
+the PES, and suggests that a robust way of deriving the V1D potential is by fitting and integrating
+its derivatives, rather than by directly fitting the energies.
+S12
+
+Figure S6: Left-hand side: total energy variation of the cluster as a function of the dO1O2 distance
+(V1D). Right-hand side: sum of the energy gradients with respect to qO1 and qO2 variations
+projected along the O1O2 direction, for classical simulations at different temperatures. This
+corresponds to ∂V1D/∂dO1O2, resulting in the force that drives the O1-O2 stretching mode.
+In Fig. S7, we study the V2D(dO1O2, δ) potential depending on the proton coordinate δ, at
+various (fixed) dO1O2 distances. In the left column, we show ∂V2D/∂δ in a contour plot as
+a function of both dO1O2 and δ. Positive (negative) values of ∂V2D/∂δ are coloured in red
+(blue). The white region indicates the extrema of the 2D-PES. The classical proton is clearly
+asymmetric for dO1O2 ≳ 2.37 ˚A, with a minimum departing from the δ = 0 axis. In the right
+S13
+
+100 K
+-103.903
+-103.904
+-103.905
+(Ha)
+V1D
+-103.906
+-103.907
+-103.908
+-103.909
+2.2
+2.3
+2.4
+2.5
+2.6100 K
+0.1
+0.05
+0
+0.05
+0.1
+2.2
+2.3
+2.4
+2.5
+2.6250 K
+-103.886
+-103.887
+-103.888
+-103.889
+-103.89
+(Ha)
+-103.891
+-103.892
+-103.893
+-103.894
+103.895
+-103.896
+2.2
+2.3
+2.4
+2.5
+2.6
+(A250 K
+0.1
+0.05
+-0.05
+0.1
+2.2
+2.3
+2.4
+2.5
+2.6350 K
+-103.87
+103.872
+103.874
+-103.876
+(Ha)
+103.878
+-103.88
+-103.882
+103.884
+-103.886
+-103.888
+2.2
+2.3
+2.4
+2.5
+2.6
+(A350 K
+0.1
+0.05
+-0.05
+-0.1
+2.2
+2.3
+2.4
+2.5
+2.6column, the same information is provided by superposing ∂V2D/∂δ plotted as a function of δ
+and taken at fixed dO1O2 distances.
+Figure S7: Left column: contour plot of ∂V2D/∂δ as a function of both dO1O2 and δ. Right
+column: superposition of ∂V2D/∂δ, plotted as a function of δ at various (fixed) dO1O2 values.
+The force acting on H+ projected along the O1O2 direction is given by −∂V2D/∂δ. Notice
+that the size of the (dO1O2, δ) space accessible by MD to sample these quantities increases as a
+function of the temperature.
+S14
+
+100 K
+0.4
+Ha/A
+0.12
+0.3
+0.10
+0.08
+S
+0.06
+0.2
+0.04
+0.02
+0.00
+-0.02
+0.1
+-0.04
+0
+2.3
+2.4
+2.5
+2.6
+(A100 K
+dO00=2.345
+0.08
+d00-2.375
+d00=2.405
+dO0=2.435
+0.06
+d00=2.465
+d00=2.495
+d00=2.525
+0.04
+d00-2.555
+0.02
+0
+0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)250 K
+0.4
+Ha/A
+0.12
+0.3
+0.10
+0.08
+S
+0.06
+0.2
+0.04
+0.02
+0.00
+-0.02
+0.1
+-0.04
+0
+2.3
+2.4
+2.5
+2.6
+(A)250 K
+d00=2.345
+0.08
+d00=2.375
+d00=2.405
+dO0=2.435
+0.06
+d00=2.465
+T
+d00=2.495
+d00=2.525
+0.04
+d00-2.555
+0.02
+0
+0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)350 K
+0.4
+Ha/A
+0.12
+0.3
+0.10
+0.08
+0.06
+0.2
+0.04
+0.02
+0.00
+-0.02
+0.1
+-0.04
+0
+2.3
+2.4
+2.5
+2.6
+(A)350 K
+d00=2.345
+0.08
+d00-2.375
+d00=2.405
+dO0=2.435
+0.06
+d00=2.465
+d00=2.495
+d00-2.525
+0.04
+d00=2.555
+0.02
+0
+0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)S5
+Projected two-dimensional PES
+Using the data obtained in Sec. S4, let us determine an analytic form for the V2D(dO1O2, δ)
+potential, which depends on both dO1O2 and δ coordinates. This will take into account the
+variation of the proton-oxygen potential along the proton shuttling mode as the distance between
+the two inner water molecules varies.
+We first derive the V1D potential between the two water molecules, which depends only on
+the dO1O2 stretching coordinate, by fitting the derivatives shown in Fig. S6, for the simulation
+at 100 K, which yields less noisy datapoints than the one at higher temperatures. As fitting
+function, we choose the Morse potential, such that:
+V1D(x) = bMorse (exp(−2cMorse(x − dMorse)) − 2 exp(−cMorse(x − dMorse))) − bMorse,
+(13)
+where we have chosen to set the zero of energy at the potential minimum. The results of the fit
+are plotted in Fig. S8, together with the potential derivatives evaluated by classical MD driven
+by QMC forces at 100 K, 250 K and 350 K.
+Figure S8: Fit of the QMC estimates of ∂V1D/∂dO1O2 at 100 K. As fitting function we have used
+the derivative of the V1D Morse potential, as defined in Eq. 13.
+From this analysis, the estimated equilibrium distance between two water molecules in the
+S15
+
+100K
+0.08
+250K
+350K
+100K μ
+0.06
+eguilibrium condition
+Morse fitting function
+0.04
+0.02
+-0.02
+-0.04
+-0.06
+-0.08
+2.2
+2.3
+2.4
+2.5
+2.6Zundel core of the protonated water hexamer is 2.408 ˚A at 100 K, in good agreement with the
+analysis based on the radial distribution function reported in Fig. 2 of the main text.
+While the data derived from QMC-MD simulations are less noisy at 100 K, they however
+explore a smaller phase space, due to a probability density distribution more localised in the
+(dO1O2, δ) space at lower temperatures. This turns out to be a problem, if one aims at estimat-
+ing the behavior of the V2D(dO1O2, δ) potential not only around its equilibrium geometry but
+also over its tails. A way to overcome this issue within the projection framework described in
+Sec. S4, is to sample the projected potential from QMC-MD simulations carried out at higher
+temperatures. As clearly shown in Fig. S7, at 250 K and 350 K the V2D behavior can be eval-
+uated on a much larger window in both δ and dO1O2 directions. Moreover, we can increase the
+statistics of higher temperatures datapoints by averaging the 250 K and 350 K estimates.
+Figure S9: Fit of the QMC forces using ∂V1D/∂x as fitting function, where the Morse potential
+V1D(x) is defined in Eq. 13 and the fitted dataset is taken by averaging the outcome of 250 K
+and 350 K simulations.
+We then fit the V1D potential in Eq. 13 by using a dataset averaged over 250 K and 350 K.
+The corresponding Morse potential fit is reported in Fig. S9. From this analysis, the equilibrium
+distance between two water molecules in the Zundel core of the protonated water hexamer is
+2.425 ˚A at ≈ 300 K, again in a satisfactory agreement with the analysis based on the radial
+S16
+
+100K
+0.1
+average of 250K and 350K
+equilibrium condition
+Morse fitting function
+0.05
+-0.05
+-0.1
+2.2
+2.3
+2.4
+2.5
+2.6
+2.7distribution function reported in Fig. 2 of the main text. Fitting over these datapoints leads to
+an increase of the equilibrium distance by 0.16 ˚A as the temperature is raised from 100 K to ≈
+300 K. The average based on the radial distribution function of the full VMC-MD simulations
+yields a cluster expansion of ≈ 0.25 ˚A.
+The Morse potential determined from points computed at 100 K and the one from points
+averaged over 250 K and 350 K are plotted in Fig. S10, where the two fitting functions are
+superimposed. The ZPE analysis described in the main text of the paper is carried out using the
+dataset averaged over 250 K and 350 K. As one can see in Fig. S10, in the energy range below
+1000 K, the two curves are just shifted from one another, having nearly the same curvature
+around the minimum. Therefore, the conclusions on the ZPE effect reached by using a model
+potential projected at larger temperatures would not be different from the ones one could reach
+using the potential derived at 100 K.
+Figure S10:
+V1D determined from classical MD at 100 K and from the averaged dataset of
+classical MD at 250 K and 350 K. The energy is expressed in Kelvin. The horizontal and
+vertical dashed lines are guides for the eye.
+As a second step, we derive the V2D(dO1O2, δ) potential. For every dO1O2 slice, in Fig. S11 we
+plot the estimated values of the ∂V2D/∂δ derivative as a function of δ, computed by averaging
+over the 250 K and 350 K classical MD samples, as we did for the V1D potential.
+S17
+
+Morse potential from average of 250K and 350K
+Morse potential from 100K
+2000
+1500
+1000
+500
+0
+2.3
+2.4
+2.5
+2.6Figure S11: Fit of the QMC forces using ∂VdO1O2(x)/∂x as fitting function for different dO1O2,
+where the potential VdO1O2(x) is defined in Eq. 14. The points are calculated as average over the
+two temperatures of 250 K and 350 K.
+S18
+
+average over 250 K and 350 K
+d00=2.315
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+d00=2.345
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+dO0=2.375
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+d00=2.405
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+dO0=2.435
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+dO0=2.465
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+d00=2.495
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+dO0=2.525
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+dO0=2.555
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)average over 250 K and 350 K
+dO0=2.585
+0.08
+Landau fitting function
+0.06
+0.04
+0.02
+0
+-0.02
+-0.04
+-0.06
+-0.08
+-0.4
+-0.3
+-0.2
+-0.1
+0
+0.1
+0.2
+0.3
+0.4
+8 (A)At every dO1O2, we fit the derivative of the energy with respect to δ, by using a symmetric
+quartic function, i.e. a Landau potential, as fitting model for the energy dependence:
+VdO1O2(x) = aLandau + bLandaux2 + cLandaux4
+at fixed dO1O2 distance.
+(14)
+The fits for selected dO1O2 values are also reported in Fig. S11. The parameters aLandau, bLandau
+and cLandau have thus an implicit dependence on dO1O2, which need to be further included in the
+full V2D(dO1O2, δ) function . We found that a good parametrisation for bLandau is given by:
+bLandau(dO1O2) = α + βdO1O2,
+(15)
+while for cLandau is:
+cLandau(dO1O2) = ϵ exp(−γdO1O2).
+(16)
+Note that the dO1O2-dependence in Eq. 16 guarantees that the potential in Eq. 14 always binds
+for ϵ > 0. Fig. S12 demonstrates how this dependence, shown by the parameters evolution, is
+well taken into account by the functional forms in Eqs. 15 and 16.
+Figure S12: Fit of the bLandau and cLandau dependence on the dO1O2 distance, based on the func-
+tional forms in Eqs. 15 and 16.
+From Eq. 15 and its fitting parameters, the bifurcation point turns out to be located at
+dsymm ≈ 2.37 ˚A, in quite good agreement with the relaxation of the ground state geometry.
+S19
+
+x? Landau term
+0.15
+Landau b evolution
+Landau b evolution fit
+0.1
+0.05
+0
+-0.05
+0.1
+-0.15
+-0.2
+-0.25
+-0.3
+2.3
+2.4
+2.5
+2.6x4 Landau term
+3.5
+Landau c evolution
+Landau c evolution fit
+3
+2.5
+2
+1.5
+1
+2.3
+2.4
+2.5
+2.6The final 2D potential V2D(dO1O2, δ) is thus fully determined by the following function:
+V2D(dO1O2, δ) = aLandau(dO1O2) + bLandau(dO1O2)δ2 + cLandau(dO1O2)δ4,
+(17)
+with bLandau(dO1O2) and cLandau(dO1O2) already defined in Eqs. 15 and 16, respectively, while
+aLandau(dO1O2) is defined as follows:
+aLandau(dO1O2) = V1D(dO1O2) + ∆(dO1O2).
+(18)
+In the above Equation, ∆(dO1O2) is the proton barrier of the Landau potential VdO1O2(x) in Eq. 14,
+such that the bottom of V2D(dO1O2, δ) at a given dO1O2 distance follows exactly the Morse poten-
+tial V1D in Eq. 13. In particular, ∆(dO1O2) reads:
+∆(dO1O2) =
+�
+0,
+if dO1O2 ≤ dsymm
+b2
+Landau(dO1O2)
+4cLandau(dO1O2),
+otherwise.
+(19)
+The resulting 2D potential V2D(dO1O2, δ) and its derivative with respect to δ are drawn in the
+contour plot of Fig. S13.
+∂
+∂δV2D(dO1O2, δ) compares very well with the same quantity directly
+Figure S13: Left panel: contour plot of the V2D(dO1O2, δ) 2D model potential. Right panel: con-
+tour plot of the model-potential derivative ∂
+∂δV2D(dO1O2, δ), to be compared with the contour plot
+of the mid- and bottom-left panels of Fig. S7, directly obtained from MD sampled datapoints.
+evaluated by QMC-driven classical MD at both 250 K and 350 K, as shown in Fig. S7, mid- and
+bottom-left panels. This is an a posteriori check of the quality of our 2D-PES determination.
+S20
+
+V2D(do,O,,8) from the QMC-MD fitting procedure
+0.4
+K
+3000
+0.3
+2500
+2000
+0.2
+1500
+1000
+500
+0.1
+0
+0
+2.3
+2.4
+2.5
+2.6aV2d(do,0,8)/08
+0.4
+Ha/A
+0.12
+0.3
+0.10
+0.08
+0.06
+0.2
+0.04
+0.02
+0.00
+-0.02
+0.1
+-0.04
+0
+2.3
+2.4
+2.5
+2.6As we have seen, there is a residual temperature dependence in the determination of V2D(dO1O2, δ),
+due to the projection scheme employed. Using a range of temperatures T ∈ [250, 350] K guar-
+antees an optimal sampling of the configuration space during the MD, allowing for a more
+extended determination of the 2D-PES model. In the main text of the paper, we used the func-
+tion plotted in Fig. S13 to carry out an anharmonic vibrational analysis of the shuttling mode.
+The range of temperatures at which the model potential V2D(dO1O2, δ) has been derived is con-
+sistent with the temperatures where the PT shows a “sweet spot”, supporting the outcome of
+our analysis.
+S6
+Proton transfer: adiabatic events versus quantum tunnel-
+ing
+The picture unveiled in this work proves that the synergy of NQEs and thermal effects is fun-
+damental to understand PT in an aqueous environment. Beside the ZPE, NQEs can contribute
+to the proton diffusion by means of instantaneous tunneling, which can further accelerate the
+PT dynamics. Both adiabatic crossing boosted by the ZPE, and instantaneous tunneling are
+plausible and non-competing scenarios in our system. As we have seen, the former is certainly
+favoured by the shortness of dO1O2 in the short-Zundel configurations, where the barrier is ab-
+sent along the shuttling trajectory δ, while the latter could sustain PT events even in case of high
+barriers, such as in Eigen-like configurations.
+In order to assess the role played by quantum tunneling, we evaluate the localisation level of
+the excess proton during its dynamics, by computing the root-mean-square (RMS) displacement
+correlation functions[33], RdOH+(τ) = ⟨|dOH+(0) − dOH+(τ)|2⟩, in imaginary time τ ∈ [0, βℏ],
+with β = 1/kBT and dOH+ = |qO − qH+|. For localised states, trapped in potential energy
+minima, RdOH+(τ) is flat in the intermediate τ range, while, for delocalised states, RdOH+(τ) is
+roughly parabolic [33]. A quantum particles undergoing a tunneling event will look like a free
+S21
+
+particle with parabolic behavior, as unaffected by the tunneled potential energy barrier.
+Figure S14:
+Root mean square displacement R(τ) in quantum imaginary time τ ∗
+∈
+[0, βℏ/M] ≡ [0, 1] for the proton displacement with respect to the side oxygen atoms,
+dOH+ = |qO − qH+|, in the core of the H13O+
+6 cation. Calculations are performed at 100 K,
+250 K and 350 K, reported in panels a), b) and c), respectively. Samples are taken from the
+instanton population, and averages are performed in a species-selected way: short-Zundel (gray
+points), elongated-Zundel (yellow points) and Eigen-like species (green points) are separated,
+according to the dO1O2 distance at which they occur. As reference, the root-mean-square dis-
+placement of the free proton at the given temperature is also reported in red solid lines.
+The evolution of the RMS displacement correlations functions RdOH+(τ) with the temper-
+ature is depicted in Fig. S14 for the instanton configurations, the most relevant for the PT de-
+scription. Also in this case, we distinguish instantons belonging to the three different regimes.
+A striking difference is observed among the three temperatures investigated, i.e. 100 K, 250 K
+and 350 K. For the lowest temperature (Fig. S14(a)), the TS correlation function RdOH+,TS(τ)
+is flat, i.e. more localised, in all regimes. At intermediate temperatures (Fig. S14(b)), within
+the “sweet spot” range, the RdOH+,traj(τ) measured in the distorted-Eigen configurations is the
+closest to the free particle behavior, while the short-Zundel averages are clearly bound by the
+confining symmetric potential. This suggests that some PT events in the distorted Eigen, which
+need to overcome taller barriers, could be enhanced by quantum tunneling, as additional PT
+channel, beside the very effective short-Zundel TS mechanism. At the highest temperature
+S22
+
+1.2
+2
+a)
+b
+c)
+Short Zundel
+Elongated Zundel
+1.0
+1.0
+1.0
+Distorted Eigen
+free particle
+0.8
+0.8
+0.8
+0.6
+0.6
+0.6
+0.4
+0.4
+0.4
+0.2
+0.2
+0.2
+100 K
+250 K
+350 K
+0.0
+0.0
+0.0
+0
+0.2
+0.4
+0.6
+0.8
+0
+0.2
+0.4
+0.6
+0.8
+0
+0.2
+1
+0.4
+0.6
+0.8
+1
+π/β
+/β
+/β(Fig. S14(c), all RdOH+,traj(τ) are very close to the free particle. However, in this case, thermal
+effects, rather than quantum tunneling, make the instantons behave like free particles.
+S23
+
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+
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new file mode 100644
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf,len=2009
+page_content='Thermal dependence of the hydrated proton and  optimal proton transfer  F´elix Mouhat,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1 Matteo Peria,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  Tommaso Morresi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3 Rodolphe Vuilleumier,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  Antonino Marco Saitta,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2 and Michele Casula2∗  1Saint Gobain Research Paris,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  39,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Quai Lucien Lefranc,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 93300 Aubervilliers,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' France  2IMPMC,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Sorbonne Universit´e,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' CNRS,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' MNHN,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' UMR 7590,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  4 Place Jussieu,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 75252 Paris,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' France  3 ECT*-Fondazione Bruno Kessler∗,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  286 Strada delle Tabarelle,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 38123,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Trento,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Italy  4 ´Ecole normale sup´erieure,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' PSL Research University,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Sorbonne Universit´e,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' CNRS,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' D´epartement de Chimie,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' PASTEUR,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  24 Rue Lhomond,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 75005 Paris,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' France  ∗To whom correspondence should be addressed;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' E-mail: michele.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='casula@upmc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='fr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Water is a key ingredient for life and plays a central role as solvent in many  biochemical reactions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' However, the intrinsically quantum nature of the hy-  drogen nucleus, revealing itself in a large variety of physical manifestations,  including proton transfer, gives rise to unexpected phenomena whose descrip-  tion is still elusive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Here we study, by an unprecedented combination of state-  of-the-art quantum Monte Carlo methods and path-integral molecular dy-  namics, the structure and hydrogen-bond dynamics of the protonated water  hexamer, the fundamental unit for the hydrated proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We report a remark-  1  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='01825v1  [cond-mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='mtrl-sci]  4 Jan 2023  ably low thermal expansion of the hydrogen bond from zero temperature up to  300 K, owing to the presence of short-Zundel configurations, characterised by  proton delocalisation and favoured by the synergy of nuclear quantum effects  and thermal activation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The hydrogen bond strength progressively weakens  above 300 K, when localised Eigen-like configurations become relevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Our  analysis, supported by the instanton statistics of shuttling protons, reveals that  the near-room-temperature range from 250 K to 300 K is a “sweet spot” for  proton transfer, and thus for many phenomena depending on it, including life.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  1  Introduction  For more than 200 years and the seminal work of von Grotthus, the properties of the hydrated  proton H+  (aq) have intrigued the scientific community [1, 2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Despite significant advances, the  exact role of the solvated proton in proton transfer (PT) reactions in chemical and biological  systems is not fully elucidated yet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The textbook picture is that the hydrated proton exists as  classical hydronium cation H3O+, but it looks more appropriately described as a delocalised  charge defect shared by multiple molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The spread of this charge defect blurs the identity  of the excess proton among two limiting structures, namely the Zundel[3] and the Eigen[4] ions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Indeed, the hydrated proton Infrared (IR) spectrum displays a combination of a few discrete  absorption bands on top of an absorption continuum, broadly extended over the entire spectrum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Neither the symmetrically solvated hydronium H9O+  4 (Eigen) ion, nor the equally shared proton  in the H5O+  2 (Zundel) ion, can individually rationalise this characteristic IR fingerprint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Models  involving fast inter-conversions between these two ionic species are also shown to fail[5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  To deal with these issues, Stoyanov et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [6] have introduced the stable H13O+  6 species, the  protonated water hexamer, which is Zundel-type in the sense that the excess proton is equally  shared between two water molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The core of the cluster is characterised by a central  2  oxygen-oxygen distance dO1O2 that, however, is more elongated than in the Zundel cation[7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  On the other hand, recent Molecular Dynamics (MD) simulations suggest the existence of a  distorted, nonsymmetric Eigen-type cation, remaining at the heart of a dynamical charge defect  spanning multiple water molecules [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, the protonated water hexamer represents the  smallest protonated water cluster for which both of these characteristic binding motifs coexist[9,  10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It is the simplest one that can provide a meaningful description of the hydrated proton in  water.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The main protonated hexamer configurations are represented in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 1, for both Zundel-  and Eigen-like forms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The protonated hexamer Potential Energy Surface (PES) has been partially explored by  IR spectroscopy [11, 12, 13] and electronic structure calculations performed within Density  Functional Theory (DFT), Møller-Plesset (MP2), and Coupled Cluster (CC) approaches, also  supplemented by Machine Learning techniques, [14, 12, 9, 11, 15, 16] confirming that the two  structures introduced above are the lowest energy isomers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The quantum nature of the proton  however induces a delocalised structure on this PES.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In this work, we apply MD simulations fully retaining the nuclear quantum nature of the  atoms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In particular, the quantum proton, described within the Feynman path integral (PI) ap-  proach, evolves in a very accurate PES estimated by means of Quantum Monte Carlo (QMC).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  This stochastic technique introduces an intrinsic noise, which affects the forces driving the ion  dynamics and, consequently, the simulation temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Relying on the generalised fluctuation-  dissipation theorem, a Langevin-based approach has been developed to address this issue for  classical [17] and quantum [18] ions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It allows one to sample microscopic configurations in the  canonical ensemble with an unprecedented level of quantum accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Details of the method  are provided in the Methods Section and in Secs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S1 and S2 of the Supplementary Information  (SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  We find that the hydrogen bond (H-bond) mediated by the hydrated proton shows a remark-  3  ably low thermal expansion from zero temperature up to 300 K, with a nearly temperature-  independent length that becomes shorter than the classical-ion counterpart in the [200-350] K  temperature range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' A non-trivial behaviour of the H-bond has also been found in H-rich crys-  tals and ferroelectric materials, such as the potassium dihydrogen phosphate (KDP)[19], first  detected by Ubbelohde in 1939 upon isotopic substitution[20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the latter case, the lighter the  hydrogen, the shorter the H-bond.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This was interpreted as a quantum manifestation of proton  delocalisation, strengthening the H-bond.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the present situation, the strength of the H-bond re-  sults from a non-trivial cooperation of nuclear quantum effects (NQEs) and thermal activation,  as we will show in this work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, NQEs strongly affect the vibrational levels of the proton  shuttling mode bridging the central O1 and O2 oxygen atoms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' These levels are then thermally  occupied according to the dO1O2 distance of a given configuration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We can thus distinguish three  regimes (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 1): (i) “short-Zundel” configurations with the shortest dO1O2, where the shut-  tling proton feels a quadratic potential and it is perfectly shared between the two central water  molecules;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' (ii) “elongated-Zundel” configurations for intermediate dO1O2, comprising the equi-  librium distance, where a potential energy barrier starts to develop in between O1 and O2 and  the proton is delocalised only due to NQEs;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' (iii) “distorted-Eigen” configurations at even larger  dO1O2, where the central barrier is large enough that the hydrated proton is localised on one of  the two flanking water molecules, forming an Eigen-like complex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We will see that the occur-  rence of short-Zundel configurations is key to understand the H-bond thermal robustness and  to enhance the proton transfer dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Despite being energetically disfavoured by the short  dO1O2 distances at the classical level, these configurations are populated thanks to the synergistic  action of NQEs and temperature, yielding a sweet spot for proton transfer in the [250-300] K  temperature range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  4  2  Results and discussion  Thermal expansion of the H-bond  To rationalise our main outcome, we first study the zero-  temperature classical geometry and PES of the protonated water hexamer, and compare it with  the Zundel cation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' While the latter system misses a large part of water solvation effects, the  former includes the full contribution of the first and second shells of the solvated proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The  zero-temperature results are reported in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1 of the SI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We simply highlight here that the  Variational Monte Carlo (VMC) equilibrium O1-O2 distance is found to be dO1O2 = dmin =  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3930(5) ˚A, in good agreement with MP2 calculations, the most widely used post Hartree-  Fock theory to study water clusters (see Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2 of the SI for a more extended comparison  between VMC and MP2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' VMC has a milder scale with the system size than MP2, allowing  one to perform extensive calculations of the protonated hexamer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At variance with the Zundel  cation[21, 22], the protonated hexamer equilibrium geometry is asymmetric, implying that the  global minimum is split into a double well, separated by an energy barrier between the two  central water molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This barrier vanishes at dO1O2 = dsymm ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='38 ˚A, a distance that  separates the short Zundel below from the elongated-Zundel configurations above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The height  of the barrier is less than 100 K (in kB units) at dmin, rapidly increasing as a function of dO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We  therefore expect several consequences on the hydrated proton distribution and on its mobility at  finite temperature, once the NQEs are taken into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  To understand how the dynamics of the hydrated proton evolves with temperature, QMC-  driven ab initio MD simulations are relevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Such calculations are carried out for both classical  and quantum nuclei of the H13O+  6 ion, within the temperature interval T ∈ [50 − 350] K, thanks  to the methodological developments detailed in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [18] and in the Methods Section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At these  conditions, the clusters are stable during the simulated time frame (≈ 30 ps), allowing us to  access the thermal properties of the hydrated proton and the O1H+O2 bond over an extended  5  temperature range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  From our QMC-MD simulations, we extract the normalised Pair Correlation Functions  (PCFs) gO1O2 for the two oxygen atoms O1 and O2 of the cluster core (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The expected  broadening of the PCFs due to nuclear quantisation is significant over the whole temperature  range (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2(b)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Only at temperatures as high as 350 K, the classical gO1O2 (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2(a)) starts  resembling the quantum distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This implies that the NQEs cannot be neglected for tem-  peratures up to this value, above ambient conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We also notice that, when comparing to  the Zundel ion results[23], the peak position is shifted up by at least ∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='01 ˚A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, it ap-  pears that the H13O+  6 cluster frequently adopts elongated-Zundel configurations[24, 25, 26] at  the lowest temperatures considered here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is at variance with the protonated water dimer,  where the hydrated proton lives in a single minimum symmetrically located between the two  water molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Focusing our attention to ⟨dO1O2⟩ (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2(c)), its classical and quantum behaviours are re-  markably different as a function of temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' On the one hand, the classical dO1O2 keeps  increasing with temperature, as more energy is given to the intermolecular vibration modes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' On  the other hand, the quantum dO1O2 displays a nearly flat behaviour with the cluster temperature,  up to 300 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This very low thermal expansion extended over a wide temperature range leads  to a temperature regime where dO1O2 for the quantum system become shorter than the classical  values at the same temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is clearly seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We will come back to this  point later.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Finally, as the temperature further increases, the NQEs reduction weakens the central H-  bond strength.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Consequently, dO1O2 spreads out, due to stochastic fluctuations of the core and  the solvent, and a more classical regime is reached, when the averaged dO1O2 values for classical  and quantum nuclei meet again.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The PCF distributions display longer tails, with more config-  urations covering regions with dO1O2 ∈ [2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 − 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='7] ˚A, and the peak position rapidly shifts to  6  larger values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Configurations with such a large ⟨dO1O2⟩ are of distorted-Eigen type[24, 27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  A cooperative thermal-quantum species: the short-Zundel ion  To refine our structural  analysis, we compute the bidimensional distribution function ρ2D, which correlates the oxygen-  oxygen (O1O2) and the oxygen-proton (O1/2H+) distances, and study its temperature depen-  dence ρ2D = ρ2D(T).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 3, we show the contour plot of the temperature-driven ρ2D  variation (see also Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2 of the SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' By taking ρ2D(250 K) as reference, four temperature  variations are explored: 100 K, 200 K, room temperature (RT), and 350 K (from the top to the  bottom of Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In the classical protonated hexamer (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 3, left column), rising the temperature from 250  K up to 350 K tends to stretch ⟨dO1O2⟩, by promoting configurations from the elongated Zundel  (blue central distribution with dO1O2 ∈ [2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='38, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5] ˚A in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 3) to an Eigen-like arrangement  with larger dO1O2 and a proton much more localised on one of the two central oxygen atoms  (red wings).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The situation is reversed at lower temperatures (100 K and 200 K) if compared to  the 250 K reference, with positive (red) variations in the elongated Zundel and negative (blue)  variations in the wings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, for classical nuclei, there is a progressive depletion of the elon-  gated Zundel and a corresponding population of the distorted-Eigen wings upon temperature  rise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Short-Zundel configurations, highlighted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 3 by a gray background, seem to play a  very marginal role in the temperature-driven density distribution shift.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The scenario is strikingly different with quantum nuclei (right column), particularly at the  lowest temperatures (100 K and 200 K).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In this regime, distorted-Eigen configurations are barely  populated or depleted, and the density shift upon rising temperature takes place between the  elongated-Zundel region and the short-Zundel sector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The latter is significantly more populated  at 250 K than at lower temperatures at the expense of the elongated Zundel, which instead loses  density with respect to the classical counterpart at the same temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  7  In the higher-temperature limit, at 350K, NQEs are less relevant and, by consequence,  the classical and quantum variations have a qualitatively similar behaviour.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In both classi-  cal and quantum case, we notice the presence of red wings at large oxygen-oxygen distances  (dO1O2 ∈ [2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='7] ˚A), which are the signature of thermally activated Eigen-like states, with  a strongly localised proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is related to less frequent elongated-Zundel configurations,  indicated by the depleted distribution for dO1O2 < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 ˚A, confirming that the distorted-Eigen  configurations are indeed promoted by high temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For quantum nuclei, the correspond-  ing depletion goes well below the elongated-Zundel region, by touching also short-Zundel con-  figurations, down to dO1O2 ∼ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3 ˚A, at variance with the classical case, where the short-Zundel  configurations are not involved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  To interpret these results, we first construct an accurate effective potential by projecting  the full PES, computed during QMC-driven classical MD calculations, onto the degrees of  freedom mostly relevant to understand the dynamics of the hydrated proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' These are the  dO1O2 distance and the proton sharing coordinate δ, referenced to the midpoint of the O1H+O2  complex: δ ≡ ˜dO1/2H+ − dO1O2/2, with ˜dO1/2H+ the O1/2-H+ distance projected onto the O1O2  direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The resulting two-dimensional (2D) potential is V2D = V2D(dO1O2, δ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We refer the  reader to Secs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S4 and S5 of the SI for technical details about the PES projection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We highlight  that the potential V2D is derived here at VMC quality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We also notice that δ is the vibrational  coordinate of the proton shuttling mode, while dO1O2 is related to the stretching mode of the two  water molecules in the cluster core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Given V2D(dO1O2, δ), we then proceed to quantize the variable δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, while dO1O2 can  be taken as classical, for it is related to the motion of heavier oxygen atoms of mass mO, the  δ coordinate must be quantised, owing to the light mass (mH) of the hydrated proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At the  leading order in 2mH/(mO + mH), we separate the stretching mode from the shuttling one,  by invoking a Born-Oppenheimer type of approximation for the two species.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We finally solve  8  quantum-mechanically the Hamiltonian of a proton in the potential Vδ ≡ V2D(α, δ)|α=dO1O2 at  fixed dO1O2 value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 4(a-c) we plot the ground state distribution and eigenvalues obtained  for three distances, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' at dO1O2=2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='375 ˚A, in the short-Zundel region close to the boundary  between the short and the elongated Zundel, at dO1O2= 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='495 ˚A, in the elongated-Zundel region  close to the frontier between the elongated Zundel and the distorted Eigen, and finally at dO1O2=  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='585 ˚A, deep into the distorted Eigen regime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  One can notice three different quantum behaviours of the vibrational shuttling mode, that  provide a more quantitative ground to the three-regime distinction made at the beginning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the  short Zundel, Vδ is indeed a quadratic potential with a single minimum at the core center, which  widens as dO1O2 gets close to dsymm ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='38 ˚A, a distance where it becomes quartic because  its curvature changes sign.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The ground state energy, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' the zero point energy (ZPE) of the  shuttling mode, decreases as the potential widens, as reported in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 4(d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the elongated  Zundel, a central barrier starts to develop, with a ground-state proton distribution that stays  uni-modal thanks to a ZPE larger than its height, till dO1O2 ≃ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 ˚A, where the ZPE equals  the barrier height.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In this regime, for dO1O2 ∈ [dsymm, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 ˚A], the ZPE is particularly small, due  to the quartic nature of Vδ, and weakly dO1O2-dependent, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 4(d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Finally, for  dO1O2 > 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 ˚A, we enter the distorted-Eigen regime, with an even larger central barrier (> 1000  K), such that the quantum proton is instantaneously localised in one of the two wells, and its  distribution is then bimodal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The ZPE starts to rise again as dO1O2 is stretched, with a slope  steeper - in absolute value - than the ZPE decrease in the short Zundel, because it is now set by  the much deeper lateral minima of the double-well potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This can be seen again in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 4(d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  We can now correct the classical O1-O2 potential, defined as VO1O2 ≡ V2D(dO1O2, δ)|δ=δmin,  where δmin is the V2D minimum at fixed dO1O2 value, by adding the ZPE ∀dO1O2, obtained from  the quantisation of the shuttling mode δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The resulting potential is plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 4(e).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Amaz-  ingly, the anharmonic classical VO1O2 potential becomes harmonic after ZPE-correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It is  9  a consequence of the much larger ZPE in the distorted-Eigen configurations than in the short  Zundel, which compensates for the underlying VO1O2 anharmonicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This rationalises two main  features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' On the one hand, it explains the very low thermal expansion of ⟨dO1O2⟩, being the aver-  age position in a harmonic potential temperature-independent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' On the other hand, it proves that  NQEs enhance the occurrence of short-Zundel configurations upon heating, while the distorted  Eigen is penalised by its large ZPE with respect to the classical counterpart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Above RT, the distorted Eigen configurations will eventually become dominant again.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This  can be understood within this framework as well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, thermal excitations are energetically  more available in the distorted Eigen, where the spacing between the ZPE and the first-excited  state shrinks, and higher excited states are piled up more densely than in the short and elongated  Zundel (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 4(a-c)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Optimal proton transfer from instantons statistics  The analysis made so far highlights the  paramount importance of the NQEs to set the non-trivial temperature behaviour of the H13O+  6  cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At this stage, direct information about the excess proton dynamics along the QMC-  PIMD trajectory is necessary to estimate more quantitatively its impact on the PT processes  occurring in the system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  One way to achieve this goal is by analysing the statistics of selected transition-state (TS)  configurations, defined by means of instanton theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Within the PI formalism, the instanton  path seamlessly connects the reactants and products minima, along the minimal action trajec-  tory, periodic in the quantum imaginary time τ = βℏ[28].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It provides a generalisation of the TS  theory for anharmonic quantum systems[29], and it has been very recently applied in a QMC  framework [30, 31], by efficiently recovering the proper scaling of ground-state tunneling rates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  TS configurations are therefore identified as those where each half of the instanton path is lo-  cated on either side of the central O1O2 midpoint, sampled during the QMC-PIMD dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  10  With the aim at resolving the contribution of the three different regimes to the PT dynamics,  we collect the instanton events and compute their statistical distribution as a function of dO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  We plot the instanton density distribution function in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 5(a) at various temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To  deepen our analysis, we compute also the cumulative density distribution function in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 5(b),  after normalising it based on the algorithmic frequency of the instanton occurrences, as counted  during our QMC-PIMD simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Although this does not give direct access to real-time  quantities, the ring-polymer MD with Langevin thermostat has been shown to yield physically  reliable information on frequencies and frequency variations[32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Note that the coupling with  the Langevin thermostat is kept constant across the full temperature range analysed here[32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The fully integrated frequency distribution gives the total proton hopping frequency, plotted in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 5(c) as a function of temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This shows a clear maximum located in the [250 − 300]  K temperature range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Consequently, we expect the hydrated proton mobility to be optimal in  a near-RT window, with a maximised Grotthus diffusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To understand the source of this  temperature “sweet spot”, in the same panel (c) we plot the contribution to the total frequency  of instanton events occurring in the short-Zundel region.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is yielded by the cumulative  frequency distribution of panel (b) evaluated at the boundaries between short and elongated  Zundel, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' at dO1O2 = dsymm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The short-Zundel contribution to the total frequency shows  a peak of the same intensity as the total one in the same temperature range, clearly pointing  to the key role played by thermally activated short-Zundel configurations to the PT dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The short-Zundel arrangement enables instantaneous proton jumps between the two sides of the  cation, since there is no barrier to cross.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, the “sweet spot” constitutes the best compromise  between acquiring enough thermal energy to access short-distance configurations, boosted by  NQEs, and controlling the amplitude of the chemical (covalent or H-) bonds fluctuations, that  might trap the proton into an asymmetric well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, at larger temperatures (> 300 K), the  onset of distorted-Eigen and the corresponding fall of short-Zundel configurations localize the  11  hydrated proton around its closest oxygen atom, thus reducing its shuttling probability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Beside this PT mechanism, which is adiabatic in nature and driven by the synergy of ZPE  and thermal effects, NQEs could also contribute to the proton diffusion by means of instanta-  neous tunneling, which can further accelerate the PT dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' By computing the root-mean-  square (RMS) displacement correlation functions[33] over the instantons population, we veri-  fied that tunneling events could take place only in the distorted Eigen and in the intermediate  temperature range (see Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S6 of SI for a detailed analysis).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This additional PT channel has  however a marginal effect with respect to the main mechanism unveiled here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 5(c)  shows that the “sweet spot” is mainly due to PT events originating in short-Zundel configura-  tions, where quantum tunneling is not relevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  3  Conclusions  Using unprecedentedly accurate QMC-PIMD simulations of the H13O+  6 cation at finite temper-  ature, we found a remarkably low thermal expansion of the protonated water hexamer core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It  stems from a cooperative action of both NQEs and thermal effects, which leads to the emer-  gent behaviour of short-Zundel species as PT booster, where the excess proton is perfectly  shared between two neighbouring water molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The relevance of short-Zundel configura-  tions is enhanced by NQEs, which instead penalize the distorted-Eigen states, having a larger  ZPE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the intermediate temperature range, comprising RT, the occurrence of short-Zundel  events is maximised by thermal population, leading to a “sweet spot” in the PT dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Around these temperatures, distorted-Eigen states can still contribute to PT with quantum tun-  neling processes, although occurring at much lower rates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The cluster core spreads out again at  larger temperatures, as soon as stronger thermal fluctuations favor the formation of more clas-  sical distorted-Eigen structures, where the proton gets strongly localised in one of the flanking  molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  12  The short-Zundel quantum species is crucial for an efficient proton diffusion, as the short-  ness of its structure enables a fast charge redistribution during the adiabatic PT process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Very  recent progress in ultrafast broadband two-dimensional (2D) IR spectroscopy[34, 35] allowed  to probe the vibrational properties of protonated water at vibrational frequencies around the hy-  drated proton stretching mode, by measuring the lowest-lying excitations in the mid-infrared  continuum[35].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  These state-of-the-art experiments revealed a strongly inhomogeneous be-  haviour of the pump-probe spectra, implying large structural distributions in proton asymmetry  and O1O2 distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Therefore, the traditional “Zundel limit”[3] needs to be revisited and ex-  tended, in order to cover the broad range of structures detected experimentally[36, 37].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In par-  ticular, the occurrence of qualitatively different short hydrogen-bond configurations, straight-  forwardly connected with the short-Zundel species described here, has been detected and high-  lighted in a recent fully solvated (HF2)−(H2O)6 experiment through femtosecond 2D IR spec-  troscopy in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The present work crucially extends those findings by providing a temper-  ature resolved analysis of the short hydrogen-bond events and by revealing their fundamental  relation with the PT dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  While proton transfer and proton transport occur in a variety of environments, from so-  lutions to membrane proteins and fuel-cell membranes, the protonated water hexamer is the  smallest cluster to incorporate most of the PT experimental features and solvation effects at the  leading order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Our findings thus call for further efforts to explore the temperature behaviour of  the proton dynamics and transport both in aqueous systems and in other environments, more  specifically for biological systems around life conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  13  4  Methods  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  Zero-temperature electronic structure calculations  Before running finite-temperature calculations, we build a quantum Monte Carlo (QMC) vari-  ational wave function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The molecular dynamics (MD) will develop on the potential energy  surface (PES) generated by the variational energy of this wave function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' All zero- and finite-  temperature calculations have been carried out with the TurboRVB code[39].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We choose the  variational ansatz such that the chemical accuracy in the binding energy of the Zundel ion and  water dimer is reached.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We highlight the fact that benchmarking the binding energy is much  stricter than taking energy differences of geometries around the minimum, because the config-  urations involved in the binding energy are very different.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The variational wave function |Ψq⟩ we used in our work is written as a Jastrow Antisym-  metrised Geminal Power (JAGP) product[40]  Ψq(x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' , xNel) = Jq(r1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' , rNel)ΨAGP,q(x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' , xNel).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (1)  The set {xi = (ri, σi)}i=1,.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=',Nel represents spatial and spin coordinates of the Nel electrons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The JAGP wave function has been described extensively described elsewhere[41, 42, 43,  44].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Here, we report its main ingredients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The Bosonic Jastrow factor is written as a product of  one-body, two-body and three/four-body terms Jq = J1,qJ2,qJ3,q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The one body term reads  J1,q  = exp  �  −  Nel  �  i  N�  j  (2Zj)3/4u  �  (2Zj)1/4|ri − qj|  �  �  (2)  with u(|r − q|) = 1−e−b|r−q|  2b  and b is a variational parameter, which satisfies the electron-ion  Kato cusp conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' N the number of atoms and Zj the electric charge of the j-th atom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the  protonated hexamer Hamiltonian, the hydrogen keeps the bare Coulomb potential, while for the  oxygen atoms are replaced by the Burkatzki-Filippi-Dolg (BFD) pseudopotential[45], smooth  at the electron-ion coalescence points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, J1,q is applied only to the hydrogen atom.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The  14  two-body correlations are dealt with by the higher-order Jastrow factors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The two-body Jastrow  factor is defined as  J2,q = exp  � Nel  �  i<j  u(|ri − rj|)  �  ,  (3)  where u is a function of the same form as in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' (2), but with a different variational parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The three-four body Jastrow factor is  J3,q = exp  � Nel  �  i<j  ΦJq(ri, rj)  �  ,  (4)  with  ΦJq(ri, rj) =  N  �  a,b  NJ  basis  �  µ,ν  ga,b  µ,νΨJ  a,µ(ri − qa)ΨJ  b,ν(rj − qb),  (5)  where N J  basis is the number of the basis set functions ΨJ  a,µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We used optimally contracted gemi-  nal embedded orbitals (GEOs)[46] as basis set, expanded over a primitive O(3s,2p,1d) H(2s,1p)  Gaussian basis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The convergence study of the water dimer binding energy as a function of the  Jastrow GEO expansion is reported in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1 of the SI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The Fermionic part of the wave function is expressed as an antisymmetrised product of the  spin singlet geminals or pairing (AGP) functions Φq(xi, xj):  ΨAGP,q(x1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' , xNel) = ˆA [Φq(x1, x2), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' , Φq(xNel−1, xNel)] .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (6)  The spatial part φq(ri, rj) of the spin singlets Φq(xi, xj) is expanded over N AGP  basis optimally  contracted GEOs, such that  φq(ri, rj) =  N  �  a,b  NAGP  basis  �  µ,ν  λa,b  µ,ν ¯ΨAGP  a,µ (ri − qa)¯ΨAGP  b,ν  (rj − qb).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (7)  The AGP GEOs are linear combination of primitive O(5s5p2d) H(4s2p) Gaussian basis func-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We highlight that the Fermionic part is fully optimised at the QMC level for each MD  step, and not generated by on-the-fly DFT calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  15  The GEOs are very effective in reducing the total number of variational parameters, by  keeping a high level of accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This makes the wave function optimisation[47, 40, 48] much  more efficient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Dealing with a compact wave function is very important, if one wants to use it  as variational ansatz in a MD simulation, because in a MD framework the wave function needs  to be optimised at every MD iteration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, the wave function optimisation is by far the most  time consuming step of our QMC-driven MD approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Previous works on the Zundel ion[44, 18] found that the optimal balance between accuracy  and computational cost for the determinantal part is reached by the O[8]H[2] contracted GEO  basis, in self-explaining notations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As the protonated water hexamer is a very similar system,  in this work we used the same O[8]H[2] GEO contraction for the AGP part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Moreover, we  further simplified the variational wave function previously developed for the Zundel ion, by  contracting also the Jastrow basis set, using the same GEO embedding scheme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We found that  the O[6]H[2] GEO basis set for the Jastrow factor is a very good compromise between accuracy  and number of parameters, as we checked in the water dimer (see Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1 of the SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The  final accuracy is about 1 kcal/mol in the dissociation energy of the water dimer, and supposedly  it is much higher around the stable geometries of water clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, we used the O[6]H[2]  GEO basis set for the Jastrow factor, and the O[8]H[2] GEO basis for the AGP part in all our  subsequent MD simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For the protonated water hexamer, this results into a total number  of 6418 variational parameters, comprising ga,b  µ,ν in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 5, λa,b  µ,ν in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 7, the parameters of the  homogeneous one-body (Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2) and two-body (Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 3) Jastrow factors, and the linear coefficients  of the Jastrow and determinantal basis sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  16  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  Finite-temperature calculations  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  Path Integral Langevin Dynamics  At finite temperature, we carried out path integral Langevin dynamics simulations to include  NQEs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To do so, we used the recently developed algorithm published in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [18], which com-  bines a path integral approach with very accurate Born-Oppenheimer (BO) forces computed by  QMC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It is an efficient approach, alternative to the coupled electron ion Monte Carlo (CEIMC)  developed by Ceperley and coworkers[49, 50, 51].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The intrinsic noise of the QMC force esti-  mator is treated by the noise correction scheme developed in Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [17, 52, 18], which is based  on the fulfilment of the fluctuation-dissipation theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This implies that the friction matrix γ  governing the dumped dynamics is related to the random force η via the α matrix:  α (q)  =  2kBTγ (q) ,  (8)  ⟨ηi (t) ηj (t′)⟩  =  αi,j (q) δ (t − t′) ,  (9)  with q the vector of nuclear coordinates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The q-dependence comes from the QMC noise cor-  rection, implemented through the relations:  α (q)  =  γBO/(2kBT) + ∆0αQMC (q)  (10)  α  QMC  i,j (q)  =  ⟨(fi (q) − ⟨fi (q)⟩)⟩ ⟨(fj (q) − ⟨fj (q)⟩)⟩ ,  (11)  where αQMC in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 11 is the covariance matrix of QMC ionic forces, measuring their stochastic  fluctuations, and γBO and ∆0 parameters taking values for an optimal Langevin dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The  random force η is then used to thermalise the system to a target temperature, according to the  Langevin thermostat of Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The quantum particles are described by necklaces extended in the imaginary time interval  [0, ℏβ], with β = 1/(kBT), following the quantum-to-classical isomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This imaginary  time interval is divided into M slices, the so-called “beads”, leading to an effective classical  17  system of NM particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The path integral Langevin dynamics we developed in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [18] is  very efficient, because the quantum harmonic forces and the Langevin thermostat - thermalising  the quantum degrees of freedom - are evolved together by means of an exact propagator, without  Trotter breakup.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The evolution of quantum particles in a thermal bath `a la Langevin represents a  quantum Ornstein-Uhlenbeck dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Therefore, we dubbed our integration scheme as “path  integral Ornstein Uhlenbeck dynamics (PIOUD)”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The algorithm is detailed in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In order to evolve the system and to sample the thermal quantum partition function, nuclear  forces must be estimated at each iteration by computing the gradients f = −∇qV (q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The  potential energy surface V (q) is evaluated by VMC, namely:  V (q) = ⟨Ψq|H(q)|Ψq⟩  ⟨Ψq|Ψq⟩  ,  (12)  where |Ψq⟩ is the QMC wave function, which minimizes the expectation value of H(q) for  each bead configuration q(k), according to the Born-Oppenheimer approximation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The electronic variational wave function depends on the coordinates q(k) of the k-th bead  in two ways.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Directly, through the explicit dependence on the ion positions provided by the lo-  calised basis set, and in an indirect way, through the wave function parameters optimised at each  q(k), in compliance with the Born-Oppenheimer approximation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' While the former dependence  is of leading order, the latter can be neglected in a first approximation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' A clever way to do so  is to average the optimal parameters across different beads, by gaining a significant fraction of  statistics in the QMC energy minimisation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' More precisely, the beads are gathered in groups of  Ngroups members each, to share the same set of wave function parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is called “bead  grouping approximation”, and it has been introduced in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Once the number of groups Ngroups is set for the beads, the electronic wave function is op-  timised at each new ionic position generated by the dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is done by energy minimi-  sation via the most advanced optimisation techniques[42, 48].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Between two consecutive steps  18  of ion dynamics, one needs to perform Nopt steps of energy minimisation, in an iterative fash-  ion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Nopt must be large enough to converge the wave function for each new ionic configuration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Thus, this parameter is tuned such that the BO approximation is fulfilled, and the dynamics  follows the correct PES along the PIOUD trajectories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  During the dynamics, the GTO exponents in both the Jastrow and the AGP part of the  wave function are kept frozen to make the simulation stable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Due to the continuity of the  nuclear trajectories, the number of energy minimisation steps is significantly smaller than the  one required for a wave function optimisation from scratch.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  There is a set of sensitive parameters one needs to tune to have stable and unbiased simula-  tions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' They are:  (i) Convergence for quantum effects set by M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In our calculations, we used M= 32 for  T= 300 − 400 K and M= 64 for T= 200 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The bead grouping approximation is made  with Ngroup = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Therefore the whole ring shares the same wave function parameters,  except for the nuclear coordinates;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (ii) Time step δt for the integration of the equations of motion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We used δt = 1 fs for a  controlled time integration error, yielding a difference between the virial and primitive  estimators of the quantum kinetic energy below a 25 mHa threshold along all the trajec-  tories;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (iii) A stable target temperature is reached despite the QMC noise by setting the parameters  γBO and ∆0, defining the α matrix in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We used γBO = 0 and ∆0 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 δt,  optimal values for other similar systems, such as the Zundel ion[18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Indeed, the simu-  lation is efficient when the damping in the BO sector is minimised.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The thermalisation  of the system is guaranteed thanks to the optimal damping condition[53] applied to the  internal modes of the ring-polymer, with the damping parameter of the center-of-mass  19  translational modes set to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='231 fs−1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (iv) To enforce the fulfilment of the BO approximation, we allowed for Nopt = 5 iterative  wave function optimisation steps at each MD iteration, such that the electronic energy  minimum is reached within the statistical accuracy for every ionic configuration, and the  PES is sampled without stochastic bias.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  Classical Langevin Dynamics  For classical MD calculations, we used an improved variant of the original algorithm developed  by Attaccalite and Sorella[17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This variant has been detailed in Refs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [52, 18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' It includes a  better integration scheme, involving a Langevin noise touching both coordinates and momenta,  which are therefore correlated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  As in the PIOUD calculations, relevant parameters are the time step δt = 1 fs, the QMC  noise correction parameters γBO = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2 fs−1 and ∆0 = δt, and the number of QMC optimisation  steps per nuclear iteration Nopt = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Acknowledgments  FM, RV, AMS and MC acknowledge Dominik Marx for useful discussions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' MP, RV, AMS and MC  thank the CNRS for the 80PRIME doctoral grant allocation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' FM and MC acknowledge computational  resources provided by the PRACE projects number 2016133322 and 2017153936.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' MC thanks GENCI  for providing computational resources at TGCC and IDRIS under the grant number 0906493, and the  Grands Challenges DARI for allowing calculations on the Joliot-Curie Rome HPC cluster under the  project number gch0420.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' TM and MC are grateful to the European Centre of Excellence in Exascale  Computing TREX-Targeting Real Chemical Accuracy at the Exascale, which partially supported this  work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This project has received funding from the European Unions Horizon 2020 Research and Innova-  tion program under Grant Agreement No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 952165.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  20  short Zundel  elongated Zundel  distorted Eigen  Figure 1: Different regimes of the protonated water hexamer H13O+  6 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Left panel: short-Zundel  configuration with a Zundel center (H5O+  2 ) in colors and its first solvation shell (4 H2O) in  gray shades.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Central panel: elongated Zundel with the quantum nature of hydrogen atoms  highlighted by the full representation of its imaginary-time positions in a PI configuration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Right  panel: distorted-Eigen configuration with an Eigen cation (H9O+  4 ) in colors accompanied by  two solvating water molecules (2 H2O) in gray shades.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The O1, O2 and H+ labels are used  throughout the paper to refer to the corresponding atoms, as indicated here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  21  HH+H  02a) classical  b) quantum  c)  Figure 2:  Classical (panel a)) and quantum (panel b)) oxygen-oxygen gO1O2 pair correlation  functions of the H13O+  6 ion as a function of temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The dashed vertical lines indicate  the average ⟨dO1O2⟩ distance for each simulation, at the corresponding temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The dotted  vertical line is located at the classical equilibrium geometry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Panel c) shows the T-dependence  of the ⟨dO1O2⟩ average distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The classical equilibrium geometry is represented by a short-  dashed horizontal black line.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At 250 K and 300 K the oxygen-oxygen distance is shortened by  NQEs with respect to the classical counterpart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  22  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='48  classical  quantum  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='46  A  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='44  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='42  O,02 a  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='40  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='38  0  50  100 150 200 250 300 350 400  T (K)100K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='18  +++++  200K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='16  250K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='14  300K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='12  350K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='18  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='16  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='14  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='12  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='25 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='35 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='45  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='55  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  O,O2 distance (A)Classical particles  Quantum particles  Short  Zundel  Elongated  Zundel  Distorted  Eigen  Short  Zundel  Elongated  Zundel  Distorted  Eigen  Figure 3: Difference between bidimensional oxygen-oxygen/oxygen-proton distributions ρ2D  obtained by QMC-driven LD simulations for classical (left panels) and quantum (right panels)  particles, computed at different temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The bidimensional distribution computed at 250  K is taken as reference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Positive (negative) regions are in red (blue) color.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The black filled  circles correspond to the zero-temperature equilibrium geometries of the H13O+  6 ion at a fixed  dO1O2 distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The coloured background highlights the three different regimes explained in the  paper: the short Zundel (gray), the elongated Zundel (yellow), and the distorted Eigen (green)  species.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  23  d)  e)  Short  Zundel  Elongated  Zundel  Distorted  Eigen  Figure 4: NQEs on the shuttling mode, and their impact on the O1-O2 interatomic potential  VO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We quantize the proton shuttling mode δ, defined as the displacement along the segment  connecting the two oxygen atoms in the core of the cluster from its mid-point position.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We  study the ground-state wave function and the first 5 eigenvalues for the confining potential Vδ,  as a function of dO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Panels a), b) and c) report the ground state wave function and the lowest  5 energy levels for dO1O2= 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='375, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='495 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='585 ˚A, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In panel d), the variation of  the zero-point (ground-state) energy (ZPE) as a function of dO1O2 is explicitly plotted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' While  the ZPE dependence is very flat in the elongated-Zundel region (depicted by the yellow shaded  area), the ZPE increases in both short-Zundel (gray shaded area) and distorted-Eigen (green  shaded area) regions, with a much steeper slope in the latter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In panel e), the ZPE is added to the  classical interatomic potential VO1O2 (solid blue line) to yield the quantum-corrected effective  interatomic potential (solid dark-pink line) between the two inner oxygen atoms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  24  quantuminteratomicpotential  classical interatomic potential  2000  1500  >  1000  500  0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='25  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='35  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='45  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='55  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='65  do,O,  (A)ZPE of shuttling mode  2000  1500  ZPE (K)  1000  500  0guantum interatomic potential  classical interatomic potential  2000  1500  Vo,02  1000  500  0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='25  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='35  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='45  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='55  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='655th energy level  4th energy level  a)  3rd energy level  8000  1st energy level  confining potential  6000  ground state  do,O, = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='375 A  4000  2000  0  b)  8000  6000  do,O, = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='495 A  S  ¥4000  V  2000  0  c)  8000  6000  = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='585 A  4000  2000  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0  shuttling displacement  (A)a)  b)  c)  Figure 5: a) Instanton distribution resolved as a function of the dO1O2 distance for different  temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' b) Cumulative distribution of a) normalised by the occurrence frequency of the  instanton (proton hopping) events during the PIMD simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' c) Proton hopping frequency  as a function of temperature, together with the contribution coming from the short Zundel con-  figurations, with dO1O2 < dsymm = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='38 ˚A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The dsymm value is reported as vertical dashed line in  panels a) and b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Here, we report simulations performed also at 400 K, a temperature at which  the cluster is still stable or meta-stable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='025  full contribution  short Zundel events  proton hopping frequency (1/fs)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='020  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='015  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='010  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='005  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='000  0  50  100 150 200 250 300 350 400  T (K)50 K  20  IIIIII  100 K  150 K  instanton distr (1/A)  200 K  15  250 K  300 K  350 K  10  5  cumulative frequency distr (1/fs)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='01  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='00  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='25  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='35  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='45  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='55  O,O distance (  (A)Supplementary information  S1  Zero-temperature electronic structure calculations  S1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  Preparation and optimisation of quantum Monte Carlo (QMC) wave  function  As described in the Methods Section, before running finite-temperature calculations, we opti-  mize a QMC variational wave function |Ψq⟩ at zero temperature, written as a Jastrow Antisym-  metrised Geminal Power (JAGP) ansatz[40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' During the finite-temperature molecular dynam-  ics, energy and forces are computed at the variational Monte Carlo (VMC) level, based on the  variational optimisation of the QMC wave function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Both Jastrow and AGP expansions are de-  veloped over a primitive O(3s2p1d) H(2s1p) and O(5s5p2d) H(4s2p) Gaussian basis functions,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The primitive basis sets are then contracted using the geminal embedded orbitals  (GEOs) scheme[46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Previous works on the Zundel ion[44, 18] found that the optimal balance between accuracy  and computational cost for the determinantal part is reached by the O[8]H[2] contracted GEO  basis, in self-explaining notations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As the protonated water hexamer is a very similar system, in  this work we used the same O[8]H[2] GEO contraction for the AGP part.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Moreover, we further  simplified the variational wave function previously developed for the Zundel ion, by contract-  ing also the Jastrow basis set, using the same GEO embedding scheme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We tried different  contraction sets, and tested them on the water dimer dissociation energy curve, as reported in  Fig S1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The water dimer is a stringent benchmark for the quality of our wave function, as it has  a chemical complexity similar to the Zundel ion, with the main difference of being charge neu-  tral.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Charge neutrality allows us to directly probe the Jastrow capability of controlling charge  fluctuations in the system, a fundamental property when coupled with the AGP determinantal  part[54].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S1  Figure S1: Water dimer dissociation energy curve as a function of the oxygen-oxygen distance  obtained by VMC, using different contracted basis sets in the Jastrow factor of a Jastrow-Slater  wave function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Each trial wave function is built using the same basis set for the determinantal  part, which is optimised together with the various Jastrow factors tested here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The black curve  indicates the reference CCSD(T) result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  As shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S1, we find a systematic improvement as the number of GEOs orbitals  increases, with the O[6]H[2] set yielding energies very close to the Jastrow primitive basis set  reference at all oxygen-oxygen distances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As reported in Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S1, this is obtained with a number  p of variational parameters significantly smaller than the one of the primitive basis set expan-  sion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Thus, we used the O[6]H[2] GEO basis set for the Jastrow factor, and the O[8]H[2] GEO  basis for the AGP part in all our subsequent molecular dynamics (MD) simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For the  protonated water hexamer, this results into a total number of 6418 variational parameters, com-  prising ga,b  µ,ν, λa,b  µ,ν, the parameters of the homogeneous one-body and two-body Jastrow factors,  and the linear coefficients of the Jastrow and determinantal basis sets (see Methods Section for  a detailed description of the wave function parameters).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S2  0  1  F  Binding energy (kcal/mol)  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  2  (kcaVmol)  5  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  3  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  4  T  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  T  Level of theory  Primitive Jastrow  HH  O[41Hr11 Jastrow  O[6iH[1i Jastrow  5  O[6]H[2] Jastrow  E  CCSD(T) from B3LYP  3  4  5  6  7  8  Distance between oxygens (A)Basis set  p  Ebind (kcal/mol)  Primitive Jastrow and primitive determinant  6303  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='46(8)  Primitive Jastrow and O[8]H[2] GEO determinant  2089  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='40(8)  O[6]H[2] GEO Jastrow and O[8]H[2] GEO determinant  1283  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='26(8)  Table S1:  Water dimer binding energies for QMC variational wave functions obtained with  different types of basis set contractions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The corresponding number p of variational parameters  is also reported.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  A more extended description of the variational wave function can be found in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' [44].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  Comparison between QMC and other electronic structure methods  To probe the microscopic rearrangement which triggers proton transfer (PT) processes in the  protonated water hexamer at finite temperature, it is necessary to determine the potential energy  surface (PES), in particular around the equilibrium geometry of the cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At variance with the  Zundel cation, the protonated hexamer minimum energy configuration is asymmetric, implying  that the hydrated proton is not equally shared between the two central water molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S2, we report the equilibrium position of the hydrated proton H+ - expressed as  distance dH+O1 (dH+O2) from the flanking oxygen atom O1 (O2) - as a function of the distance  dO1O2 between the two central oxygen atoms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S2 shows the equilibrium geometries at  constrained dO1O2 obtained by various methods: density functional theory (DFT) with the PBE  functional (dark green), DFT modified to include dispersive van der Waals (vdW) interactions  in the DF2 implementation[55] (magenta), variational Monte Carlo (blue circles) and Møller-  Plesset (MP2) (red triangles).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The dO1O2 distance corresponding to the global minimum is  indicated by a vertical dashed line for each method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The PBE functional predicts a short-Zundel-like symmetric global minimum, which is erro-  neous.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' More generally, this functional gives a poor description of the proton location when one  stretches the dO1O2 distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' After inclusion of dispersion effects in the DF2 functional, the ge-  ometric properties of the system are significantly improved, displaying a better agreement with  S3  Figure S2:  Equilibrium position of the excess proton H - expressed as distance dHO1 (dHO2)  from the flanking oxygen atom O1 (O2) - as a function of the separation dO1O2 between the  two central oxygen atoms, reported for different computational methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Vertical dashed lines  indicate the equilibrium dO1O2 for each method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  both QMC and MP2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Nevertheless, the predicted equilibrium dO1O2 is too large, which leads  to an overly asymmetric cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Therefore, we expect the DF2 static barriers to be inaccurate,  which is problematic in the perspective of studying PT at finite temperature by this method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Instead, MP2 and QMC are in excellent agreement, especially around dO1O2 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4 ˚A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S2 we report the equilibrium geometries yielded by PBE, DF2, MP2 and VMC,  by showing the relevant distances involving the Zundel core of the protonated water hexamer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The VMC minimum geometry is in a very good agreement with the MP2 one, with an accurate  description of the excess proton localisation, as previously seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The largest discrep-  ancy between VMC and MP2 is for the OH intramolecular distances, which are slightly shorter  in VMC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' However, the overall evolution of equilibrium position of the hydrated proton H+ as  S4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9  PBE-DFT  DF2-DFT  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  QMC  dH02  MP2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='7  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  dHo1  dH02  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  do102  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  dH01  1  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='7  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9a function of the oxygen-oxygen distance predicted by QMC follows well the one obtained by  MP2, as one can see from Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Theory  O1O2  O1H+  H+O2  O1H1  O1H2  O2H3  O2H4  DFT-PBE  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4156  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2078  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2078  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9935  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9935  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9935  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9935  DFT-DF2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4541  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1196  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3346  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9913  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9911  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9797  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9797  MP2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3867  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1690  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2188  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9877  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9878  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9847  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9848  VMC  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3930(5)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1555(5)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2375(5)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9800(8)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9798(8)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9752(8)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='9748(8)  Table S2: Geometric properties (distances in ˚A) of the core of the protonated water hexamer  minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Comparison between different computational methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Due to the central distorted H-bond, the hydrated proton motion from one flanking water  molecule to another is conditioned by the necessary energy it should acquire to go across the  PT static barrier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This quantity is defined as the energy difference between the equilibrium  structure (asymmetric) and the symmetrised one, where the proton is located at the mid-point  of the considered dO1O2 distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' PT static barriers have been estimated at dO1O2 = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='45 ˚A and  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5 ˚A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The barriers, converted into effective temperatures, are reported in Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S3 for different  levels of theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  dO1O2 ( ˚A)  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='45 ˚A  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='50 ˚A  DFT-DF2  39  483  CCSD(T)  141  431  MP2  85  327  VMC  195 ± 25  562 ± 27  Table S3:  Static symmetrisation barriers (in Kelvin) of the H13O+  6 cation at different dO1O2  distances for various computational methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  DFT-DF2 seems unable to predict accurate PT barriers due to the misplacement of the global  energy minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This further motivates the use of correlated methods to describe the electronic  PES, such as coupled cluster CCSD(T) and MP2 theories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Their values are closer to the barriers  predicted by VMC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' They differ between each other by 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2 kcal/mol, a difference within  S5  chemical accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' However, the QMC method exhibits a milder scaling with the system size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Therefore, the QMC approach is certainly the best candidate to perform fully ab initio MD  simulations of small protonated water clusters at an affordable computational cost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S2  Finite-temperature calculations: QMC-driven classical and  quantum Langevin dynamics  We simulated the protonated water hexamer by treating the electrons at the VMC level (JAGP  wave function) and the nuclei considered as quantum particles as well, within a path integral  (PI) formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To understand the impact of quantum effects, simulations with classical nuclei  have also been performed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The Langevin dynamics (LD) algorithms used have been described  in the Methods Section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S4, we report the list of VMC+PILD simulations done.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For their importance, par-  ticularly long simulations are performed for the quantum case at temperatures of 50, 100, 200,  and 300 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Table S4: Summary of the simulations carried out in this work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In both classical and quantum  calculations, a time step δt of 1 ft is used for all temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  quantum simulations  classical simulations  T(K)  Nbeads  Niterations  Niterations  50  128  35282 100  128  52184  21454  150  64  11218 200  64  32553  20478  250  32  23912  24154  300  32  31929  22656  350  32  18489  26481  400  32  23026  27517  S6  S3  Structural properties of protonated water clusters  S3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  Role of solvation: Zundel ion versus protonated water hexamer  As mentioned in the main text of the paper, the protonated water hexamer is the smallest water  cluster including the full first-solvation shell, due to the presence of a Zundel core surrounded  by 4 solvating H2O molecules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To quantify the impact of the solvation shell on the Zundel  core, we compare in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S3 the O1-O2 potential, VO1O2 (left), and the corresponding classical  equilibrium geometry (right) of the two clusters at various dO1O2 (distance between the 2 central  oxygen atoms).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At short dO1O2, the slope of the protonated hexamer VO1O2 is slightly larger than  the Zundel one, due to a greater electrostatic repulsion because of steric hindrance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At large  dO1O2, the protonated hexamer PES is softer than the Zundel one, because the solvating H2O  molecules enhance the polarisability of the core atoms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As explained in the paper, the balance  between short- and long-range repulsion, once supplemented with the zero-point energie (ZPE),  is key to quantify the relative abundance of short-Zundel and distorted-Eigen configurations,  and thus, it allows for a quantitative understanding of the PT mechanism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  We also find the H13O+  6 equilibrium dO1O2, represented by a vertical dashed line in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S3,  to be ∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='05 ˚A larger than the H5O+  2 one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' More importantly, at variance with the Zundel cation  which is centrosymmetric, the protonated water hexamer equilibrium geometry is asymmetric  with classical ions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This fundamental symmetry modification of the PES is induced by solvation  effects, which tend to stabilize the hexamer into its elongated-Zundel configuration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This can  rationalise some THz/FTIR absorption spectroscopy fingerprints of the solvated proton[56],  which have been related to a fast inter-conversion between the (distorted-)Eigen and (short-  )Zundel forms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Furthermore, it is noteworthy that at fixed dO1O2, the predicted barriers are larger in H13O+  6  (Tab.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S3) than in the Zundel cation[44].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is clearly due to the additional price that must be  S7  Figure S3:  Comparison of the protonated water dimer and hexamer VO1O2 potential (left)  and equilibrium geometry (right) as a function of the (central) oxygen-oxygen distance dO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Vertical dashed lines indicate the corresponding equilibrium dO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Notice that VMC and lattice  regularised diffusion Monte Carlo (LRDMC)[41] energies are in nice statistical agreement for  dO1O2 ∈ [2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6] ˚A, the phase-space range explored by our MD simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  paid for the rearrangement of the molecules in the solvation shell during the PT process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  H13O+  6 bidimensional distribution functions  We report some finite-temperature properties of the H13O+  6 system, studied by looking at the  bidimensional distributions functions ρ2D, which correlate the distance between the central pro-  ton and the neighbouring oxygen atoms (dH+O1, dH+O2) with dO1O2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' They are shown in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S4  and S5, for quantum and classical simulations, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S8  12  Zundel VMC  Zundel LRDMC  HexamerVMC  Hexamer LRDMC  8  Energy [Kcal/mol]  0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  do,O, [A]1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='7  Zundel VMC  Hexamer VMC  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content='6  do,O, (A)and PT mechanism are analysed and detailed in the main text, based on the proton density  distributions shown in Figs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S4 and S5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S4  Towards an accurate modeling of the potential energy sur-  face (PES)  We exploit the calculation of VMC forces not only to perform QMC-driven classical and quan-  tum LD, but also to extract the best PES fitting functional form for the excess proton and for  the water-water interaction in the Zundel core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The final goal is to derive the two-dimensional  (2D) model potential V2D = V2D(dO1O2, δ), where dO1O2 is the distance between the two central  oxygen atoms and δ is the proton sharing coordinate, referenced to the midpoint of the O1H+O2  complex: δ ≡ ˜dO1/2H+−dO1O2/2, with ˜dO1/2H+ the O1/2-H+ distance projected onto the O1O2 di-  rection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The projection of the full interatomic potential on the restricted 2D manifold is done by  integrating the other degrees of freedom over the thermal partition function, sampled during the  MD dynamics, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' V2D(dO1O2, δ) ≡ ⟨V (q1, q2, qN−2)δ(q1 − dO1O2)δ(q2 − δ)⟩, where ⟨.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='⟩ is the  average over the partition function of the classical/quantum statistical ensemble at fixed temper-  ature, and V is the 3N-dimensional potential depending on the generalised nuclear coordinates  of the full system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Analogously, one can define the one-dimensional (1D) potential acting be-  tween O1 and O2 as V1D = V1D(dO1O2) ≡ ⟨V (q1, q2, qN−2)δ(q1 −dO1O2)⟩, according to previous  notations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Derivatives of the previous potentials with respect to dO1O2 and/or δ can be defined  in the same way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For instance, ∂V2D/∂δ ≡ ⟨∂V (q1, q2, qN−2)/∂q2 δ(q1 − dO1O2)δ(q2 − δ)⟩, and  ∂V1D/∂dO1O2 ≡ ⟨∂V (q1, q2, qN−2)/∂q1 δ(q1 − dO1O2)⟩.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Given these definitions, we can proceed with the calculations of the corresponding quantities  with the aim at modeling the potentials V1D and V2D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To do so, we will integrate the other degrees  of freedom using the classical Boltzmann distribution in ⟨.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='⟩, as generated by the QMC-driven  classical Langevin dynamics at 100, 250 and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Employing the classical partition function  S11  has the advantage that the potentials sampled in this way will tend to the original PES of the  system as β → ∞, while the quantum partition function will lead to averaged potentials biased  by quantum fluctuations even in the zero temperature limit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' To compute these quantities from  an MD sampling, the δ-functions in their definitions above are replaced by bins, whose size is  given by the spacing between neighbouring points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S6, we study the V1D(dO1O2) potential depending on the water-water distance dO1O2  (left column), and its derivative ∂V1D/∂dO1O2 (right column).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As one can see, the energy profile,  at the left-hand side, is much more noisy than the behavior of its gradient, from where we  can extract a precise value of the equilibrium dO1O2 distance, and the evolution of the potential  around the minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This shows the advantage of computing QMC forces in order to determine  the PES, and suggests that a robust way of deriving the V1D potential is by fitting and integrating  its derivatives, rather than by directly fitting the energies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S12  Figure S6: Left-hand side: total energy variation of the cluster as a function of the dO1O2 distance  (V1D).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Right-hand side: sum of the energy gradients with respect to qO1 and qO2 variations  projected along the O1O2 direction, for classical simulations at different temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This  corresponds to ∂V1D/∂dO1O2, resulting in the force that drives the O1-O2 stretching mode.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S7, we study the V2D(dO1O2, δ) potential depending on the proton coordinate δ, at  various (fixed) dO1O2 distances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the left column, we show ∂V2D/∂δ in a contour plot as  a function of both dO1O2 and δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Positive (negative) values of ∂V2D/∂δ are coloured in red  (blue).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The white region indicates the extrema of the 2D-PES.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The classical proton is clearly  asymmetric for dO1O2 ≳ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content='6column, the same information is provided by superposing ∂V2D/∂δ plotted as a function of δ  and taken at fixed dO1O2 distances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Figure S7: Left column: contour plot of ∂V2D/∂δ as a function of both dO1O2 and δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Right  column: superposition of ∂V2D/∂δ, plotted as a function of δ at various (fixed) dO1O2 values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The force acting on H+ projected along the O1O2 direction is given by −∂V2D/∂δ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content='4  8 (A)S5  Projected two-dimensional PES  Using the data obtained in Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S4, let us determine an analytic form for the V2D(dO1O2, δ)  potential, which depends on both dO1O2 and δ coordinates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This will take into account the  variation of the proton-oxygen potential along the proton shuttling mode as the distance between  the two inner water molecules varies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  We first derive the V1D potential between the two water molecules, which depends only on  the dO1O2 stretching coordinate, by fitting the derivatives shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S6, for the simulation  at 100 K, which yields less noisy datapoints than the one at higher temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As fitting  function, we choose the Morse potential, such that:  V1D(x) = bMorse (exp(−2cMorse(x − dMorse)) − 2 exp(−cMorse(x − dMorse))) − bMorse,  (13)  where we have chosen to set the zero of energy at the potential minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The results of the fit  are plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S8, together with the potential derivatives evaluated by classical MD driven  by QMC forces at 100 K, 250 K and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Figure S8: Fit of the QMC estimates of ∂V1D/∂dO1O2 at 100 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As fitting function we have used  the derivative of the V1D Morse potential, as defined in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  From this analysis, the estimated equilibrium distance between two water molecules in the  S15  100K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  250K  350K  100K μ  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  eguilibrium condition  Morse fitting function  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6Zundel core of the protonated water hexamer is 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='408 ˚A at 100 K, in good agreement with the  analysis based on the radial distribution function reported in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2 of the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  While the data derived from QMC-MD simulations are less noisy at 100 K, they however  explore a smaller phase space, due to a probability density distribution more localised in the  (dO1O2, δ) space at lower temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This turns out to be a problem, if one aims at estimat-  ing the behavior of the V2D(dO1O2, δ) potential not only around its equilibrium geometry but  also over its tails.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' A way to overcome this issue within the projection framework described in  Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S4, is to sample the projected potential from QMC-MD simulations carried out at higher  temperatures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As clearly shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S7, at 250 K and 350 K the V2D behavior can be eval-  uated on a much larger window in both δ and dO1O2 directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Moreover, we can increase the  statistics of higher temperatures datapoints by averaging the 250 K and 350 K estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Figure S9: Fit of the QMC forces using ∂V1D/∂x as fitting function, where the Morse potential  V1D(x) is defined in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 13 and the fitted dataset is taken by averaging the outcome of 250 K  and 350 K simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  We then fit the V1D potential in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 13 by using a dataset averaged over 250 K and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The corresponding Morse potential fit is reported in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' From this analysis, the equilibrium  distance between two water molecules in the Zundel core of the protonated water hexamer is  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='425 ˚A at ≈ 300 K, again in a satisfactory agreement with the analysis based on the radial  S16  100K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  average of 250K and 350K  equilibrium condition  Morse fitting function  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='7distribution function reported in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 2 of the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Fitting over these datapoints leads to  an increase of the equilibrium distance by 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='16 ˚A as the temperature is raised from 100 K to ≈  300 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The average based on the radial distribution function of the full VMC-MD simulations  yields a cluster expansion of ≈ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='25 ˚A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The Morse potential determined from points computed at 100 K and the one from points  averaged over 250 K and 350 K are plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S10, where the two fitting functions are  superimposed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The ZPE analysis described in the main text of the paper is carried out using the  dataset averaged over 250 K and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As one can see in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S10, in the energy range below  1000 K, the two curves are just shifted from one another, having nearly the same curvature  around the minimum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Therefore, the conclusions on the ZPE effect reached by using a model  potential projected at larger temperatures would not be different from the ones one could reach  using the potential derived at 100 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Figure S10:  V1D determined from classical MD at 100 K and from the averaged dataset of  classical MD at 250 K and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The energy is expressed in Kelvin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The horizontal and  vertical dashed lines are guides for the eye.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  As a second step, we derive the V2D(dO1O2, δ) potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For every dO1O2 slice, in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S11 we  plot the estimated values of the ∂V2D/∂δ derivative as a function of δ, computed by averaging  over the 250 K and 350 K classical MD samples, as we did for the V1D potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S17  Morse potential from average of 250K and 350K  Morse potential from 100K  2000  1500  1000  500  0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6Figure S11: Fit of the QMC forces using ∂VdO1O2(x)/∂x as fitting function for different dO1O2,  where the potential VdO1O2(x) is defined in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The points are calculated as average over the  two temperatures of 250 K and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S18  average over 250 K and 350 K  d00=2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='315  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  Landau fitting function  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  8 (A)average over 250 K and 350 K  d00=2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='345  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  Landau fitting function  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content='585  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  Landau fitting function  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  8 (A)At every dO1O2, we fit the derivative of the energy with respect to δ, by using a symmetric  quartic function, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' a Landau potential, as fitting model for the energy dependence:  VdO1O2(x) = aLandau + bLandaux2 + cLandaux4  at fixed dO1O2 distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (14)  The fits for selected dO1O2 values are also reported in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' The parameters aLandau, bLandau  and cLandau have thus an implicit dependence on dO1O2, which need to be further included in the  full V2D(dO1O2, δ) function .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' We found that a good parametrisation for bLandau is given by:  bLandau(dO1O2) = α + βdO1O2,  (15)  while for cLandau is:  cLandau(dO1O2) = ϵ exp(−γdO1O2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (16)  Note that the dO1O2-dependence in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 16 guarantees that the potential in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 14 always binds  for ϵ > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S12 demonstrates how this dependence, shown by the parameters evolution, is  well taken into account by the functional forms in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 15 and 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Figure S12: Fit of the bLandau and cLandau dependence on the dO1O2 distance, based on the func-  tional forms in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 15 and 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  From Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 15 and its fitting parameters, the bifurcation point turns out to be located at  dsymm ≈ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='37 ˚A, in quite good agreement with the relaxation of the ground state geometry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S19  x?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Landau term  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='15  Landau b evolution  Landau b evolution fit  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='05  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='15  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6x4 Landau term  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  Landau c evolution  Landau c evolution fit  3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  1  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6The final 2D potential V2D(dO1O2, δ) is thus fully determined by the following function:  V2D(dO1O2, δ) = aLandau(dO1O2) + bLandau(dO1O2)δ2 + cLandau(dO1O2)δ4,  (17)  with bLandau(dO1O2) and cLandau(dO1O2) already defined in Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 15 and 16, respectively, while  aLandau(dO1O2) is defined as follows:  aLandau(dO1O2) = V1D(dO1O2) + ∆(dO1O2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (18)  In the above Equation, ∆(dO1O2) is the proton barrier of the Landau potential VdO1O2(x) in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 14,  such that the bottom of V2D(dO1O2, δ) at a given dO1O2 distance follows exactly the Morse poten-  tial V1D in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In particular, ∆(dO1O2) reads:  ∆(dO1O2) =  �  0,  if dO1O2 ≤ dsymm  b2  Landau(dO1O2)  4cLandau(dO1O2),  otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  (19)  The resulting 2D potential V2D(dO1O2, δ) and its derivative with respect to δ are drawn in the  contour plot of Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  ∂  ∂δV2D(dO1O2, δ) compares very well with the same quantity directly  Figure S13: Left panel: contour plot of the V2D(dO1O2, δ) 2D model potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Right panel: con-  tour plot of the model-potential derivative ∂  ∂δV2D(dO1O2, δ), to be compared with the contour plot  of the mid- and bottom-left panels of Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S7, directly obtained from MD sampled datapoints.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  evaluated by QMC-driven classical MD at both 250 K and 350 K, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S7, mid- and  bottom-left panels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This is an a posteriori check of the quality of our 2D-PES determination.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S20  V2D(do,O,,8) from the QMC-MD fitting procedure  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  K  3000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2500  2000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  1500  1000  500  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0  0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6aV2d(do,0,8)/08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  Ha/A  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='12  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='08  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='06  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='04  0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='3  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6As we have seen, there is a residual temperature dependence in the determination of V2D(dO1O2, δ),  due to the projection scheme employed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Using a range of temperatures T ∈ [250, 350] K guar-  antees an optimal sampling of the configuration space during the MD, allowing for a more  extended determination of the 2D-PES model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' In the main text of the paper, we used the func-  tion plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S13 to carry out an anharmonic vibrational analysis of the shuttling mode.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The range of temperatures at which the model potential V2D(dO1O2, δ) has been derived is con-  sistent with the temperatures where the PT shows a “sweet spot”, supporting the outcome of  our analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S6  Proton transfer: adiabatic events versus quantum tunnel-  ing  The picture unveiled in this work proves that the synergy of NQEs and thermal effects is fun-  damental to understand PT in an aqueous environment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Beside the ZPE, NQEs can contribute  to the proton diffusion by means of instantaneous tunneling, which can further accelerate the  PT dynamics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Both adiabatic crossing boosted by the ZPE, and instantaneous tunneling are  plausible and non-competing scenarios in our system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As we have seen, the former is certainly  favoured by the shortness of dO1O2 in the short-Zundel configurations, where the barrier is ab-  sent along the shuttling trajectory δ, while the latter could sustain PT events even in case of high  barriers, such as in Eigen-like configurations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  In order to assess the role played by quantum tunneling, we evaluate the localisation level of  the excess proton during its dynamics, by computing the root-mean-square (RMS) displacement  correlation functions[33], RdOH+(τ) = ⟨|dOH+(0) − dOH+(τ)|2⟩, in imaginary time τ ∈ [0, βℏ],  with β = 1/kBT and dOH+ = |qO − qH+|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For localised states, trapped in potential energy  minima, RdOH+(τ) is flat in the intermediate τ range, while, for delocalised states, RdOH+(τ) is  roughly parabolic [33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' A quantum particles undergoing a tunneling event will look like a free  S21  particle with parabolic behavior, as unaffected by the tunneled potential energy barrier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  Figure S14:  Root mean square displacement R(τ) in quantum imaginary time τ ∗  ∈  [0, βℏ/M] ≡ [0, 1] for the proton displacement with respect to the side oxygen atoms,  dOH+ = |qO − qH+|, in the core of the H13O+  6 cation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Calculations are performed at 100 K,  250 K and 350 K, reported in panels a), b) and c), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Samples are taken from the  instanton population, and averages are performed in a species-selected way: short-Zundel (gray  points), elongated-Zundel (yellow points) and Eigen-like species (green points) are separated,  according to the dO1O2 distance at which they occur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' As reference, the root-mean-square dis-  placement of the free proton at the given temperature is also reported in red solid lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  The evolution of the RMS displacement correlations functions RdOH+(τ) with the temper-  ature is depicted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S14 for the instanton configurations, the most relevant for the PT de-  scription.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Also in this case, we distinguish instantons belonging to the three different regimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  A striking difference is observed among the three temperatures investigated, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' 100 K, 250 K  and 350 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' For the lowest temperature (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S14(a)), the TS correlation function RdOH+,TS(τ)  is flat, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' more localised, in all regimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At intermediate temperatures (Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S14(b)), within  the “sweet spot” range, the RdOH+,traj(τ) measured in the distorted-Eigen configurations is the  closest to the free particle behavior, while the short-Zundel averages are clearly bound by the  confining symmetric potential.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' This suggests that some PT events in the distorted Eigen, which  need to overcome taller barriers, could be enhanced by quantum tunneling, as additional PT  channel, beside the very effective short-Zundel TS mechanism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' At the highest temperature  S22  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  2  a)  b  c)  Short Zundel  Elongated Zundel  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='0  Distorted Eigen  free particle  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  100 K  250 K  350 K  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='0  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='2  1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='8  1  π/β  /β  /β(Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' S14(c), all RdOH+,traj(τ) are very close to the free particle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' However, in this case, thermal  effects, rather than quantum tunneling, make the instantons behave like free particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  S23  References  [1] Marx, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=': Proton transfer 200 years after von Grotthuss: Insights from ab initio sim-  ulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' ChemPhysChem 7(9), 1848–1870 (2006).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='1002/  cphc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='200600128  [2] Cukierman, S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=': Et tu, Grotthuss!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' and other unfinished stories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Biochimica et Biophys-  ica Acta (BBA) - Bioenergetics 1757(8), 876–885 (2006).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' https://doi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='org/10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='  1016/j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='bbabio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content=': Energieb¨ander der tunnelnden ¨uberschuß-protonen in fl¨ussigen  s¨auren.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Eine IR-spektroskopische untersuchung der natur der gruppierungen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content=' Part I: Elemen-  tary processes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content=' Ed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Engl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content=': Transport and spectroscopy of the hydrated proton: A molec-  ular dynamics study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content=' : The structure of the hydrogen ion (H+  aq) in  water.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content=' Chem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+page_content='E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' : The cation H13O6+: A short,  symmetric hydrogen bond.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' Science 190, 151–152 (1975)  [8] Knight, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=', Voth, G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content='A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
+page_content=' : The curious case of the hydrated proton.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/cdAzT4oBgHgl3EQf3P4R/content/2301.01825v1.pdf'}
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+MnTTS2: An Open-Source Multi-Speaker
+Mongolian Text-to-Speech Synthesis Dataset
+Kailin Liang†, Bin Liu†, Yifan Hu†, Rui Liu⋆, Feilong Bao, and Guanglai Gao
+Inner Mongolia University, Hohhot, China
+liangkailin98@foxmail.com,iframe_liu@163.com,hyfwalker@163.com
+liurui_imu@163.com, {csfeilong, csggl}@imu.edu.cn
+Abstract. Text-to-Speech (TTS) synthesis for low-resource languages
+is an attractive research issue in academia and industry nowadays.
+Mongolian is the official language of the Inner Mongolia Autonomous
+Region and a representative low-resource language spoken by over 10
+million people worldwide. However, there is a relative lack of open-source
+datasets for Mongolian TTS. Therefore, we make public an open-source
+multi-speaker Mongolian TTS dataset, named MnTTS2, for the benefit
+of related researchers. In this work, we prepare the transcription from
+various topics and invite three professional Mongolian announcers to
+form a three-speaker TTS dataset, in which each announcer records 10
+hours of speeches in Mongolian, resulting 30 hours in total. Furthermore,
+we build the baseline system based on the state-of-the-art FastSpeech2
+model and HiFi-GAN vocoder. The experimental results suggest that
+the constructed MnTTS2 dataset is sufficient to build robust multi-
+speaker TTS models for real-world applications. The MnTTS2 dataset,
+training recipe, and pretrained models are released at: https://github.
+com/ssmlkl/MnTTS2.
+Keywords: Mongolian · Text-to-Speech (TTS) · Open-Source Dataset
+· Multi-Speaker.
+1
+Introduction
+Text-to-Speech (TTS) aims to convert the input text to human-like speech [1].
+It is a standard technology in human-computer interaction, such as cell phone
+voice assistants, car navigation, smart speakers, etc. The field of speech synthesis
+has developed rapidly in recent years. Different from the traditional methods,
+which use concatenation [2], statistical modeling [3] based methods to synthesize
+speech, neural end-to-end TTS models achieve remarkable performance with the
+help of Encoder-Decoder architecture [4]. Typical models include Tacotron [5],
+Tacotron2 [1], Transformer TTS [6], Deep Voice [7], etc. To further accelerate
+⋆ : Corresponding Author is Rui Liu. †: Equal Contributions. This research was funded
+by the High-level Talents Introduction Project of Inner Mongolia University (No.
+10000-22311201/002) and the Young Scientists Fund of the National Natural Science
+Foundation of China (No. 62206136).
+arXiv:2301.00657v1  [eess.AS]  11 Dec 2022
+
+2
+Kailin Liang & Bin Liu & Yifan Hu et al.
+the inference speed, the non-autoregressive TTS models, such as FastSpeech [8],
+FastSpech2(s) [9], are proposed and become the mainstream methods of TTS.
+Note that armed with the neural network based vocoder, including WaveNet
+[10], WaveRNN [11], MelGAN [12], HiFi-GAN [13], etc., the TTS model can
+synthesize speech sounds that are comparable to human sounds.
+We note that an important factor in the rapid development of neural TTS
+mentioned above is the large scale corpus resources. This is especially true for
+languages such as English and Mandarin, which are widely spoken worldwide.
+However, low-resource language such as Mongolian [14] have been making slow
+progress in related research due to the difficulties in corpus collection. Therefore,
+building a large-scale and high-quality Mongolian TTS dataset is necessary. In
+addition, our lab have previously open-sourced a single-speaker dataset called
+MnTTS [15], which was recorded by a young female native Mongolian speaker
+and received much attention from academia and industry upon its release. This
+also shows the necessity of continuing to collect and organize Mongolian speech
+synthesis datasets and opening the baseline model’s source code.
+Motivated by this, this paper presents a multi-speaker Mongolian TTS
+dataset, termed as MnTTS2, which increases the number of speakers to three
+and increases the data size from 8 to 30 hours, with an average of 10 hours
+per speaker. The textual content has been further expanded and enriched in
+the domain. Similar with our MnTTS, MnTTS2 dataset is freely available to
+academics and industry practitioners.
+To demonstrate the reliability of MnTTS2, we combined the state-of-
+the-art FastSpeech2 [9] model and the HiFi-GAN [13] vocoder to build the
+accompanied baseline model for MnTTS2. We conduct listening experiments and
+report the Naturalness Mean Opinion Score (N-MOS) and Speaker Similarity
+Mean Opinion Score (SS-MOS) results in terms of naturalness and speaker
+similarity respectively. The experimental results show that our system can
+achieve satisfactory performance on the MnTTS2, which indicates that the
+MnTTS2 corpus is practically usable and can be used to build robust multi-
+speaker TTS system.
+The main contributions are summarized as follows. 1) We developed a multi-
+speaker TTS dataset, termd as MnTTS2, containing three speakers. The total
+audio duration is about 30 hours. The transcribed text covers various domains,
+such as sports and culture, etc. 2) We used the state-of-the-art non-autoregressive
+FastSpeech2 model to build the baseline model and validate our MnTTS2. 3) The
+MnTTS2 dataset, source code, and pre-trained models will be publicly available
+to academics and industry practitioners.
+The rest of the paper is organized as follows. Section 2 revisits the related
+works about the Mongolian TTS corpus. In Section 3, we introduce the details of
+MnTTS2, including the corpus structure and statistical information. Section 4
+explains and discusses the experimental setup and experimental results. Section
+5 discusses the challenges faced by Mongolian speech synthesis and the future
+research directions. Section 6 concludes the paper and summarizes the work and
+research of this paper.
+
+MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset
+3
+2
+Related Work
+For mainstream languages such as English and Mandarin, there are many free
+and publicly available TTS datasets. For example, LJSpeech [16] is a single-
+speaker dataset for English. To rich the speaker diversity, some multi-speaker
+TTS dataset are released, such as Libritts [17] for English and Aishell [18] for
+Chinese.
+For the low-resource language such as Mongolian, the available resources
+are pretty limited. We note that some attempts tried to improve the effect of
+TTS synthesis under low resource data with unsupervised learning [19], semi-
+supervised learning [20], and transfer learning [21] methods, etc. However, due
+to the lack of large-scale training data, all the mentioned methods are difficult
+to achieve the effect that meets the requirements of practical scenarios.
+In order to promote the development of Mongolian TTS, some works built
+their own Mongolian TTS corpus and designed various models to achieve
+good results. For example, Huang et al. established the first emotionally
+controllable Mongolian TTS system and achieved eight emotional embeddings
+by transfer learning and emotional embedding [22]. Rui Liu et al. introduced
+a new method to segment Mongolian words into stems and suffixes, which
+greatly improved the performance of the Mongolian rhyming phrase prediction
+system [23]. Immediately after that, Rui Liu proposed a DNN-based Mongolian
+speech synthesis system, which performs better than the traditional HMM [24].
+Also, he introduced the Bidirectional Long Term Memory (BiLSTM) model to
+improve the phrase break prediction step in the traditional speech synthesis
+system, making it more applicable to Mongolian [25]. Unfortunately, none of
+the Mongolian TTS dataset from the above works have been released publicly
+and are not directly available to the public. We also found that some dataset in
+related fields, such as M2ASR-MONGO [26] for Mongolian speech recognition,
+are public recently. However, the speech recognition corpus cannot be applied in
+the TTS filed due to the environment noise and improper speaking style issues
+etc.
+We previously released the single-speaker MnTTS dataset [15], called
+MnTTS. The total duration of the MnTTS is 8 hours, and it was recorded
+in a studio by a professional female native Mongolian announcer. However, the
+duration and speaker diversity still needs to be further expanded. In a nutshell,
+it is necessary to construct a high-quality multi-speaker Mongolian TTS dataset
+to further promote the Mongolian TTS research, which is the focus of this paper.
+We will introduce the details of the MnTTS2 at the following subsection.
+3
+MnTTS2 Dataset
+In this section, we first revisit the MnTTS dataset briefly and then introduce
+our MnTTS2 by highlighting the extended content.
+
+4
+Kailin Liang & Bin Liu & Yifan Hu et al.
+3.1
+MnTTS
+In the preliminary work, we presented a high-quality single-speaker Mongolian
+TTS dataset, called MnTTS [15]. The transcription of the dataset was collected
+from a wide range of topics, such as policy, sports, culture, etc. The Mongolian
+script was then converted to Latin sequences to avoid as many miscoding issues
+as possible. A professional female native Mongolian announcer was invited to
+record all the audio. A Mongolian volunteer was invited to check and re-align
+the alignment errors. The audio containing ambient noise and mispronunciation
+was removed to ensure the overall quality.
+MnTTS has received much attention from researchers in the same industry
+upon its release. Furthermore, the subset was used in the Mongolian Text-
+to-Speech Challenge under Low-Resource Scenario at NCMMSC2022 1. The
+organizers provided two hours of data for all participants to train their models.
+This competition also promotes the development of intelligent information
+processing in minority languages within China.
+3.2
+MnTTS2
+The construction pipeline of MnTTS2 consists of “Text collection and narration”,
+“Text preprocessing” and “Audio recording and audio-text alignment”. We will
+introduce them in order and then report the corpus structure and statistics.
+Text collection and narration Similar with MnTTS [15], the first step in
+building the MnTTS2 dataset is to collect a large amount of transcription. The
+natural idea for collecting such a text materials is crawl text information from
+websites and electronic books. The text topics should cover human daily usage
+scenarios as much as possible. Following this, we crawled 23, 801 sentences,
+that are rich in content and have a wide range of topics (e.g., politics, culture,
+economy, sports, etc.), to meet our requirements well. At the same time,
+we manually filtered and removed some texts with unsuitable content, which
+may involve sensitive political issues, religious issues or pornographic content.
+These contents are removed in the hope that our dataset can make a positive
+contribution to the development of Mongolian language, which is the original
+intention of our work.
+Text preprocessing Compared to mainstream languages, such as Mandarin
+and English, traditional Mongolian performs agglutinative characteristic [27].
+This makes the Mongolian letters express different styles in different contexts
+and brings a serious harmonic phenomenon [15]. In order to solve this problem,
+we transformed the texts into a Latin alphabet, instead of traditional Mongolian
+representation, for TTS training. The entire pipeline of converting Mongolian
+texts into Latin sequences is divided into three steps: encoding correction, Latin
+conversion and text regularization. The detailed description can be found in our
+previous work MnTTS [15].
+1 http://mglip.com/challenge/NCMMSC2022-MTTSC/index.html
+
+MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset
+5
+MnTTS2
+F1
+spkID_1_uttID.txt spkID_1_uttID.wav
+F2
+F3
+spkID_1_uttID.txt
+spkID_1_uttID.wav spkID_1_uttID.txt
+spkID_1_uttID.wav
+Fig. 1: The folder structure of the MnTTS2 corpus.
+Audio recording and audio-text alignment Different with the MnTTS [15],
+we invited three native Mongolian-speaking announcers to record the audio. Each
+announcer volunteered to participate and signed an informed consent form to be
+informed of the data collection and use protocol. F1, F2 and F3 are three native
+Mongolian speaking females, with F2 being a little girl and F1 and F3 being
+slightly older in grade. All recordings were done in a standard recording studio
+at Inner Mongolia University. We choose Adobe Audition 2 as the recording
+software.
+During the recording process, we asked the announcer to keeps a 0.3s pause at
+the beginning and end of each audio segment, keeps a constant distance between
+the lips and the microphone, performs a slight pause at the comma position, and
+performs an appropriate pitch boost at the question mark position.
+To ensure the quality of the recording data , we rechecked the recording data
+after completing the recording work. Specifically, we invited three volunteers
+to check each text against its corresponding natural audio. These volunteers
+are responsible for splitting the recorded audio file into sentences and aligning
+the split sentences with the text. The Mongolian text is represented by a Latin
+sequence, where each Latin word in the sequence becomes a word and each letter
+that makes up the word is called a character. Characters also include punctuation
+marks, such as commas (‘,’), periods (‘.’) , question mark (‘?’) , exclamation mark
+(‘!’) etc. Finally, we obtained about 30h of speech data, which were sampled at
+44.1kHz with a sampling accuracy of 16bit.
+Corpus structure and statistics The file structure of the MnTTS2 corpus
+is shown in Fig. 1. Each speaker’s recording file and the corresponding text
+collection are saved in a folder named after the speaker. All audios are stored in
+2 https://www.adobe.com/cn/products/audition.html
+
+6
+Kailin Liang & Bin Liu & Yifan Hu et al.
+Table 1: The statistics results of MnTTS2 dataset.
+Statistical Unit
+Speaker ID
+F1
+F2
+F3
+Character
+Total
+572016
+459213
+601366
+Mean
+79
+61
+67
+Min
+12
+2
+2
+Max
+189
+188
+190
+Word
+Total
+88209
+71245
+92719
+Mean
+12
+9
+10
+Min
+3
+1
+1
+Max
+29
+30
+29
+(a) F1
+(b) F2
+(c) F3
+(a) F1
+(b) F2
+(c) F3
+Fig. 2: Word number distributions (a, b, c) and sentence duration distributions
+(d, e, f) for all speakers of MnTTS2.
+WAV format files , sampled at 44.10kHz, and coded in 16 bits. All text is saved
+in a TXT file encoded in UTF-8. The file name of the audio is the same as the
+corresponding text file name, and the name of each file consists of the speaker,
+document ID, and corpus ID.
+The statistical results of the MnTTS2 data are shown in Table 1 and Fig. 2.
+As shown in Table 1, the entire corpus has a total of 23, 801 sentences. Take the
+speaker F1 for example, F1 with a total of 572,016 Mongolian characters, and
+the average number of characters per sentence is 79, with the shortest sentence
+
+2700
+2400
+2100
+SEGMENTS
+1800
+1500
+1200
+900
+600
+300
+0
+9-12
+2-15
+5-18
+18-21
+21-24
+>24
+2
+5
+LENGTH(WORDS)1500
+1200
+SEGMENTS
+900
+600
+300
+-
+3
+6
+9-12
+2-15
+-18
+2
+-24
+>24
+5
+8
+2
+1
+1
+LENGTH(WORDS)2400
+2100
+1800
+SEGMENTS
+1500
+1200
+900
+600
+300
+0
+9-12
+2-15
+15-18
+18-21
+21-24
+>24
+2
+LENGTH(WORDS2500
+2000
+SEGMENTS
+1500
+1000
+500
+0
+9
+DURATION(SECONDS)1200
+1000
+SEGMENTS
+800
+600
+400
+200
+0
+123
+4
+5
+6
+8
+9
+DURATION(SECONDS)2000
+1800
+1600
+1400
+SEGMENTS
+1200
+1000
+800
+600
+400
+200
+0
+80
+DURATION(SECONDSMnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset
+7
+having 12 characters and the longest sentence having 189 characters. If words
+are used as the statistical unit, the total number of words in this dataset for F1 is
+88,209, the mean value of words in each sentence is 12, the minimum value is 3,
+and the maximum value is 29. As shown in Fig. 2, we also counted the sentence
+duration to draw a histogram. Take speaker F1 for example, the word numbers
+of the sentences are concentrated in 12-15, and duration are concentrated in 4-5
+seconds. In comparison, we found that the word numbers of sentences for F2 was
+not particularly concentrated, and the duration were relatively scattered. F3, on
+the other hand, is more similar to F1, with a more obvious concentration. The
+statistics of all three speakers are in line with the normal distribution.
+4
+Speech Synthesis Experiments
+To verify the validity of our MnTTS2, we conducted Mongolian TTS experiments
+based on the FastSpeech2 model and HiFi-GAN vocoder and evaluated the
+synthesized speech using Mean Opinion Score (MOS) metric in terms of
+naturalness and speaker similarity.
+4.1
+Experimental Setup
+We use the TensorFlowTTS toolkit 3 to build an end-to-end TTS model based on
+the FastSpeech2 model. The FastSpeech2 model converts the input Mongolian
+text into Mel-spectrogram features, and then the HiFi-GAN vocoder reconstructs
+the waveform by the Mel-spectrogram features. FastSpeech2 is a state-of-the-art
+non-autoregressive [28] speech synthesis model that extracts duration, pitch,
+and energy directly from the speech waveform and uses these features as input
+conditions in training. This model can effectively solve errors such as repetition
+and word skipping, and has the advantage of fast training speed. FastSpeech2
+introduces more variance information to alleviate the one-to-many mapping
+problem. Also, the pitch prediction is improved by wavelet transform. Most of
+all, FastSpeech2 has the characteristics of fast, robust, and controllable speech
+synthesis. This is the main reason why we choose FastSpeech2. As shown in Fig.
+3, based on FastSpeech2, we implement the multi-speaker FastSpeech2 by adding
+the speaker encoder module. The speaker encoder includes speaker embedding,
+dense, and softplus layers 3. In the network architecture setting, the number of
+speakers is 3. The dimension of speaker embedding is 384. The hidden side of
+the text encoder is 384 and the number of hidden layers is 4, the hidden layer
+size of the decoder is 384 and the number of hidden layers is 4. The number
+of Conv layers of the variance predictors is 2 and the dropout rate is 0.5. The
+initial learning rate is 0.001 and the dropout rate is 0.2.
+The HiFi-GAN vocoder builds the network through a generative adversarial
+network to converts Mel-spectrogram into high-quality audio. The generator
+of HiFi-GAN consists of an upsampling structure, which consists of a one-
+dimensional transposed convolution, and a multi-receptive filed fusion module,
+3 https://github.com/TensorSpeech/TensorFlowTTS
+
+8
+Kailin Liang & Bin Liu & Yifan Hu et al.
+Character 
+Embedding
+Mongolian Scripts
+Text Encoder
+Speaker  
+Encoder
+Speaker_id
+Positional 
+Encoding
+Variance Adaptor
+Positional 
+Encoding
+Mel-spectrogram 
+Decoder
+HiFi-GAN
+MRF
+(a) Fastspeech2
+(b) HiFi-GAN
+Speaker  
+Embedding
+Fig. 3: The structure of the FastSpeech2+HiFi-GAN model. We implement the
+multi-speaker FastSpeech2 by adding the speaker encoder module.
+which is responsible for optimizing the upsampling points. HiFi-GAN, as a
+generative adversarial network, has two kinds of discriminators, including multi-
+scale and multi-period discriminators. The generagor kernel size of HiFi-GAN is 7
+and the upsampling ratio is (8,8,2,2). The list of discriminators for the cycle scale
+is (2,3,5,7,11). The Conv filters of each periodic discriminator are 8. The pooling
+type of output downsampling in the melgan discriminator is AveragePooling1D,
+the kernel size is (5,3), and the activation function is LeakyReLU. HiFi-GAN is
+trained independently of FastSpeech2. For each speaker, the generator with only
+stft loss is first trained for 100k steps, and then the generator and discriminator
+are trained for 100k steps. This gives us the corresponding vocoder for each of
+the three speakers.
+Note that a teacher Tacotron2 model trained for each speaker was used
+to extract duration from the attention contrast for subsequent FastSpeech2
+model training. For each speaker, the Tacotron2 model trained with 100k steps
+of MnTTS was used to extract the duration. After that, the multi-speaker
+FastSpeech2 model was trained with 200k steps to do the final speech generation.
+100k steps were trained for HiFi-GAN’s generator and 100k steps for jointly
+
+ku[1] x1 ConvTranspose
+stride: ku[1]/2, channels: hu/2]MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset
+9
+training the generator and discriminator. All the above models were trained on
+2 Tesla V100 GPUs.
+4.2
+Naturalness Evaluation
+For a full comparison of naturalness, we compared our baseline system,
+FastSpeech2+HiFi-GAN with the Ground Truth speech. In addition, to
+verify the performance of HiFi-GAN, we added a FastSpeech2+Griffin-Lim
+baseline model for further comparison. The Griffin-Lim algorithm can directly
+obtain the phase information of the audio to reconstruct the waveform without
+additional training. We used the Naturalness Mean Opinion Score (SS-MOS)
+[29] to assess naturalness. For each speaker, we randomly select 20 sentences
+as the evaluation set, which are not used for training. The model-generated
+audio and the ground truth audio were randomly disrupted and distributed
+to listeners. During the evaluation process, 10 native Mongolian speakers were
+asked to evaluate the naturalness of the generated 400 audio speeches in a quiet
+environment.
+The N-MOS results are given in Table 2. Ground truth speech gets the
+best performance without a doubt. FastSpeech2+HiFi-GAN outperforms the
+FastSpeech2+Griffin-Lim and achieves much closer performance to the ground
+truth. Each speaker’s N-MOS score was above 4.0 on the combination of
+FastSpeech2 and HiFi-GAN.
+Specifically, for the F1, F2, and F3, the N-MOS of FastSpeech2+HiFi-GAN
+achieved 4.02, 4.15, and 4.29 respectively, which is encouraging. This proves
+that high-quality Mongolian speech can be synthesized using MnTTS2 and the
+proposed model. In a nutshell, all results prove that our MnTTS2 dataset can
+be used to build a robust TTS system for high-quality speech generation.
+Table 2: Naturalness mean opinion score (N-MOS) results for all systems with
+95% Confidence intervals.
+System
+Speaker ID
+F1
+F2
+F3
+FastSpeech2+Griffin-Lim
+3.56±0.18
+3.59±0.04
+3.86±0.12
+FastSpeech2+HiFi-GAN
+4.02±0.18
+4.15±0.06
+4.29±0.11
+Ground Truth
+4.73±0.08
+4.70±0.14
+4.68±0.09
+4.3
+Speaker Similarity Evaluation
+We further conduct listening experiments to evaluate the speaker similarity
+performance for the FastSpeech+HiFi-GAN baseline system. The Speaker
+Similarity Mean Opinion Score (SS-MOS) results are reported in Table 3.
+We synthesized 20 audios for each speaker by FastSpeech2+HiFi-GAN
+baseline system. Ten native Mongolian-speaking volunteers were also invited
+
+10
+Kailin Liang & Bin Liu & Yifan Hu et al.
+to participate in the scoring. Each volunteer needs to evaluate whether the
+speaker is the same person or not in the synthesized and the ground truth audio.
+The SS-MOS scores for F1, F2, and F3 are 4.58, 4.04, and 4.12 respectively,
+which is encouraging. The results show that the audio synthesized by the
+FastSpeech2+HiFi-GAN system performs good performance in terms of speaker
+similarity. The highest SS-MOS score was obtained for speaker F1. Auditioning
+the audio, we can find that F1’s timbre has significant characteristics and the
+synthesized audio represents the speaker’s voice information well. In a nutshell,
+this experiment shows that the MnTTS2 dataset can be used for speech synthesis
+work in multi-speaker scenarios.
+Table
+3:
+Speaker
+Similarity
+Mean
+opinion
+score
+(SS-MOS)
+results
+for
+FastSpeech2+HiFi-GAN system with 95% Confidence intervals.
+System
+Speaker ID
+F1
+F2
+F3
+FastSpeech2+HiFi-GAN
+4.58±0.21
+4.04±0.16
+4.12±0.10
+5
+Challenges and Future Work
+With the development of “Empathy AI”, the research of emotional TTS has
+attracted more and more attention [30]. Speech synthesis in conversational
+scenarios and emotional speech synthesis are hot research topics nowadays [31].
+Furthermore, how to control the emotion category and the emotional intensity
+during speech generation is an interesting direction [32]. However, our MnTTS2
+does not involve information related to emotion category and emotion intensity.
+In future work, we will carry out a more comprehensive and in-depth expansion
+of the data to serve the development of emotional Mongolian TTS.
+6
+Conclusion
+We presented a large-scale, open-source Mongolian text-to-speech corpus, MnTTS2,
+which enriches MnTTS with more durations, topics, and speakers. Releasing
+our corpus under the Knowledge Attribution 4.0 International License, the
+corpus allows both academic and commercial use. We describe in detail
+the process of building the corpus, while we validate the usability of the
+corpus by synthesizing sounds with the FastSpeech2 model and the HiFi-GAN
+vocoder. The experimental results show that our system can achieve satisfactory
+performance on the MnTTS2, which indicates that the MnTTS2 corpus is
+practically usable and can be used to build robust multi-speaker TTS system.
+In future work, we will introduce emotional TTS dataset to further enrich our
+corpus. We also plan to compare the effects of different TTS architectures and
+model hyperparameters on the results and conduct subsequent analyses.
+
+MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset
+11
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+
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf,len=519
+page_content='MnTTS2: An Open-Source Multi-Speaker  Mongolian Text-to-Speech Synthesis Dataset  Kailin Liang†, Bin Liu†, Yifan Hu†, Rui Liu⋆, Feilong Bao, and Guanglai Gao  Inner Mongolia University, Hohhot, China  liangkailin98@foxmail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com,iframe_liu@163.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com,hyfwalker@163.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com  liurui_imu@163.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com, {csfeilong, csggl}@imu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='cn  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Text-to-Speech (TTS) synthesis for low-resource languages  is an attractive research issue in academia and industry nowadays.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Mongolian is the official language of the Inner Mongolia Autonomous  Region and a representative low-resource language spoken by over 10  million people worldwide.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' However, there is a relative lack of open-source  datasets for Mongolian TTS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Therefore, we make public an open-source  multi-speaker Mongolian TTS dataset, named MnTTS2, for the benefit  of related researchers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In this work, we prepare the transcription from  various topics and invite three professional Mongolian announcers to  form a three-speaker TTS dataset, in which each announcer records 10  hours of speeches in Mongolian, resulting 30 hours in total.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Furthermore,  we build the baseline system based on the state-of-the-art FastSpeech2  model and HiFi-GAN vocoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The experimental results suggest that  the constructed MnTTS2 dataset is sufficient to build robust multi-  speaker TTS models for real-world applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The MnTTS2 dataset,  training recipe, and pretrained models are released at: https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  com/ssmlkl/MnTTS2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Keywords: Mongolian · Text-to-Speech (TTS) · Open-Source Dataset  Multi-Speaker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  1  Introduction  Text-to-Speech (TTS) aims to convert the input text to human-like speech [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  It is a standard technology in human-computer interaction, such as cell phone  voice assistants, car navigation, smart speakers, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The field of speech synthesis  has developed rapidly in recent years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Different from the traditional methods,  which use concatenation [2], statistical modeling [3] based methods to synthesize  speech, neural end-to-end TTS models achieve remarkable performance with the  help of Encoder-Decoder architecture [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Typical models include Tacotron [5],  Tacotron2 [1], Transformer TTS [6], Deep Voice [7], etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' To further accelerate  ⋆ : Corresponding Author is Rui Liu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' †: Equal Contributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This research was funded  by the High-level Talents Introduction Project of Inner Mongolia University (No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  10000-22311201/002) and the Young Scientists Fund of the National Natural Science  Foundation of China (No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 62206136).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='00657v1  [eess.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='AS]  11 Dec 2022  2  Kailin Liang & Bin Liu & Yifan Hu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  the inference speed, the non-autoregressive TTS models, such as FastSpeech [8],  FastSpech2(s) [9], are proposed and become the mainstream methods of TTS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Note that armed with the neural network based vocoder, including WaveNet  [10], WaveRNN [11], MelGAN [12], HiFi-GAN [13], etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=', the TTS model can  synthesize speech sounds that are comparable to human sounds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  We note that an important factor in the rapid development of neural TTS  mentioned above is the large scale corpus resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This is especially true for  languages such as English and Mandarin, which are widely spoken worldwide.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  However, low-resource language such as Mongolian [14] have been making slow  progress in related research due to the difficulties in corpus collection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Therefore,  building a large-scale and high-quality Mongolian TTS dataset is necessary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In  addition, our lab have previously open-sourced a single-speaker dataset called  MnTTS [15], which was recorded by a young female native Mongolian speaker  and received much attention from academia and industry upon its release.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This  also shows the necessity of continuing to collect and organize Mongolian speech  synthesis datasets and opening the baseline model’s source code.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Motivated by this, this paper presents a multi-speaker Mongolian TTS  dataset, termed as MnTTS2, which increases the number of speakers to three  and increases the data size from 8 to 30 hours, with an average of 10 hours  per speaker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The textual content has been further expanded and enriched in  the domain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Similar with our MnTTS, MnTTS2 dataset is freely available to  academics and industry practitioners.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  To demonstrate the reliability of MnTTS2, we combined the state-of-  the-art FastSpeech2 [9] model and the HiFi-GAN [13] vocoder to build the  accompanied baseline model for MnTTS2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We conduct listening experiments and  report the Naturalness Mean Opinion Score (N-MOS) and Speaker Similarity  Mean Opinion Score (SS-MOS) results in terms of naturalness and speaker  similarity respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The experimental results show that our system can  achieve satisfactory performance on the MnTTS2, which indicates that the  MnTTS2 corpus is practically usable and can be used to build robust multi-  speaker TTS system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  The main contributions are summarized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 1) We developed a multi-  speaker TTS dataset, termd as MnTTS2, containing three speakers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The total  audio duration is about 30 hours.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The transcribed text covers various domains,  such as sports and culture, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 2) We used the state-of-the-art non-autoregressive  FastSpeech2 model to build the baseline model and validate our MnTTS2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 3) The  MnTTS2 dataset, source code, and pre-trained models will be publicly available  to academics and industry practitioners.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  The rest of the paper is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Section 2 revisits the related  works about the Mongolian TTS corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In Section 3, we introduce the details of  MnTTS2, including the corpus structure and statistical information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Section 4  explains and discusses the experimental setup and experimental results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Section  5 discusses the challenges faced by Mongolian speech synthesis and the future  research directions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Section 6 concludes the paper and summarizes the work and  research of this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset  3  2  Related Work  For mainstream languages such as English and Mandarin, there are many free  and publicly available TTS datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' For example, LJSpeech [16] is a single-  speaker dataset for English.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' To rich the speaker diversity, some multi-speaker  TTS dataset are released, such as Libritts [17] for English and Aishell [18] for  Chinese.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  For the low-resource language such as Mongolian, the available resources  are pretty limited.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We note that some attempts tried to improve the effect of  TTS synthesis under low resource data with unsupervised learning [19], semi-  supervised learning [20], and transfer learning [21] methods, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' However, due  to the lack of large-scale training data, all the mentioned methods are difficult  to achieve the effect that meets the requirements of practical scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  In order to promote the development of Mongolian TTS, some works built  their own Mongolian TTS corpus and designed various models to achieve  good results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' For example, Huang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' established the first emotionally  controllable Mongolian TTS system and achieved eight emotional embeddings  by transfer learning and emotional embedding [22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Rui Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' introduced  a new method to segment Mongolian words into stems and suffixes, which  greatly improved the performance of the Mongolian rhyming phrase prediction  system [23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Immediately after that, Rui Liu proposed a DNN-based Mongolian  speech synthesis system, which performs better than the traditional HMM [24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Also, he introduced the Bidirectional Long Term Memory (BiLSTM) model to  improve the phrase break prediction step in the traditional speech synthesis  system, making it more applicable to Mongolian [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Unfortunately, none of  the Mongolian TTS dataset from the above works have been released publicly  and are not directly available to the public.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We also found that some dataset in  related fields, such as M2ASR-MONGO [26] for Mongolian speech recognition,  are public recently.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' However, the speech recognition corpus cannot be applied in  the TTS filed due to the environment noise and improper speaking style issues  etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  We previously released the single-speaker MnTTS dataset [15], called  MnTTS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The total duration of the MnTTS is 8 hours, and it was recorded  in a studio by a professional female native Mongolian announcer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' However, the  duration and speaker diversity still needs to be further expanded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In a nutshell,  it is necessary to construct a high-quality multi-speaker Mongolian TTS dataset  to further promote the Mongolian TTS research, which is the focus of this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  We will introduce the details of the MnTTS2 at the following subsection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  3  MnTTS2 Dataset  In this section, we first revisit the MnTTS dataset briefly and then introduce  our MnTTS2 by highlighting the extended content.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  4  Kailin Liang & Bin Liu & Yifan Hu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='1  MnTTS  In the preliminary work, we presented a high-quality single-speaker Mongolian  TTS dataset, called MnTTS [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The transcription of the dataset was collected  from a wide range of topics, such as policy, sports, culture, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The Mongolian  script was then converted to Latin sequences to avoid as many miscoding issues  as possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' A professional female native Mongolian announcer was invited to  record all the audio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' A Mongolian volunteer was invited to check and re-align  the alignment errors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The audio containing ambient noise and mispronunciation  was removed to ensure the overall quality.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  MnTTS has received much attention from researchers in the same industry  upon its release.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Furthermore, the subset was used in the Mongolian Text-  to-Speech Challenge under Low-Resource Scenario at NCMMSC2022 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The  organizers provided two hours of data for all participants to train their models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  This competition also promotes the development of intelligent information  processing in minority languages within China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='2  MnTTS2  The construction pipeline of MnTTS2 consists of “Text collection and narration”,  “Text preprocessing” and “Audio recording and audio-text alignment”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We will  introduce them in order and then report the corpus structure and statistics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Text collection and narration Similar with MnTTS [15], the first step in  building the MnTTS2 dataset is to collect a large amount of transcription.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The  natural idea for collecting such a text materials is crawl text information from  websites and electronic books.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The text topics should cover human daily usage  scenarios as much as possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Following this, we crawled 23, 801 sentences,  that are rich in content and have a wide range of topics (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=', politics, culture,  economy, sports, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' ), to meet our requirements well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' At the same time,  we manually filtered and removed some texts with unsuitable content, which  may involve sensitive political issues, religious issues or pornographic content.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  These contents are removed in the hope that our dataset can make a positive  contribution to the development of Mongolian language, which is the original  intention of our work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Text preprocessing Compared to mainstream languages, such as Mandarin  and English, traditional Mongolian performs agglutinative characteristic [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  This makes the Mongolian letters express different styles in different contexts  and brings a serious harmonic phenomenon [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In order to solve this problem,  we transformed the texts into a Latin alphabet, instead of traditional Mongolian  representation, for TTS training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The entire pipeline of converting Mongolian  texts into Latin sequences is divided into three steps: encoding correction, Latin  conversion and text regularization.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The detailed description can be found in our  previous work MnTTS [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  1 http://mglip.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com/challenge/NCMMSC2022-MTTSC/index.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='html  MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset  5  MnTTS2  F1  spkID_1_uttID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='txt spkID_1_uttID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content='txt  spkID_1_uttID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content='txt  spkID_1_uttID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='wav  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 1: The folder structure of the MnTTS2 corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Audio recording and audio-text alignment Different with the MnTTS [15],  we invited three native Mongolian-speaking announcers to record the audio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Each  announcer volunteered to participate and signed an informed consent form to be  informed of the data collection and use protocol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' F1, F2 and F3 are three native  Mongolian speaking females, with F2 being a little girl and F1 and F3 being  slightly older in grade.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' All recordings were done in a standard recording studio  at Inner Mongolia University.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We choose Adobe Audition 2 as the recording  software.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  During the recording process, we asked the announcer to keeps a 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='3s pause at  the beginning and end of each audio segment, keeps a constant distance between  the lips and the microphone, performs a slight pause at the comma position, and  performs an appropriate pitch boost at the question mark position.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  To ensure the quality of the recording data , we rechecked the recording data  after completing the recording work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Specifically, we invited three volunteers  to check each text against its corresponding natural audio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' These volunteers  are responsible for splitting the recorded audio file into sentences and aligning  the split sentences with the text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The Mongolian text is represented by a Latin  sequence, where each Latin word in the sequence becomes a word and each letter  that makes up the word is called a character.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Characters also include punctuation  marks, such as commas (‘,’), periods (‘.’) , question mark (‘?’' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=') , exclamation mark  (‘!’' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=') etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Finally, we obtained about 30h of speech data, which were sampled at  44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='1kHz with a sampling accuracy of 16bit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Corpus structure and statistics The file structure of the MnTTS2 corpus  is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Each speaker’s recording file and the corresponding text  collection are saved in a folder named after the speaker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' All audios are stored in  2 https://www.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='adobe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com/cn/products/audition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='html  6  Kailin Liang & Bin Liu & Yifan Hu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Table 1: The statistics results of MnTTS2 dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Statistical Unit  Speaker ID  F1  F2  F3  Character  Total  572016  459213  601366  Mean  79  61  67  Min  12  2  2  Max  189  188  190  Word  Total  88209  71245  92719  Mean  12  9  10  Min  3  1  1  Max  29  30  29  (a) F1  (b) F2  (c) F3  (a) F1  (b) F2  (c) F3  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 2: Word number distributions (a, b, c) and sentence duration distributions  (d, e, f) for all speakers of MnTTS2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  WAV format files , sampled at 44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='10kHz, and coded in 16 bits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' All text is saved  in a TXT file encoded in UTF-8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The file name of the audio is the same as the  corresponding text file name, and the name of each file consists of the speaker,  document ID, and corpus ID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  The statistical results of the MnTTS2 data are shown in Table 1 and Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  As shown in Table 1, the entire corpus has a total of 23, 801 sentences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Take the  speaker F1 for example,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' F1 with a total of 572,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='016 Mongolian characters,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' and  the average number of characters per sentence is 79,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' with the shortest sentence  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content='DURATION(SECONDSMnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content='having 12 characters and the longest sentence having 189 characters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' If words  are used as the statistical unit, the total number of words in this dataset for F1 is  88,209, the mean value of words in each sentence is 12, the minimum value is 3,  and the maximum value is 29.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' As shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 2, we also counted the sentence  duration to draw a histogram.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Take speaker F1 for example, the word numbers  of the sentences are concentrated in 12-15, and duration are concentrated in 4-5  seconds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In comparison, we found that the word numbers of sentences for F2 was  not particularly concentrated, and the duration were relatively scattered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' F3, on  the other hand, is more similar to F1, with a more obvious concentration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The  statistics of all three speakers are in line with the normal distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  4  Speech Synthesis Experiments  To verify the validity of our MnTTS2, we conducted Mongolian TTS experiments  based on the FastSpeech2 model and HiFi-GAN vocoder and evaluated the  synthesized speech using Mean Opinion Score (MOS) metric in terms of  naturalness and speaker similarity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='1  Experimental Setup  We use the TensorFlowTTS toolkit 3 to build an end-to-end TTS model based on  the FastSpeech2 model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The FastSpeech2 model converts the input Mongolian  text into Mel-spectrogram features, and then the HiFi-GAN vocoder reconstructs  the waveform by the Mel-spectrogram features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' FastSpeech2 is a state-of-the-art  non-autoregressive [28] speech synthesis model that extracts duration, pitch,  and energy directly from the speech waveform and uses these features as input  conditions in training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This model can effectively solve errors such as repetition  and word skipping, and has the advantage of fast training speed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' FastSpeech2  introduces more variance information to alleviate the one-to-many mapping  problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Also, the pitch prediction is improved by wavelet transform.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Most of  all, FastSpeech2 has the characteristics of fast, robust, and controllable speech  synthesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This is the main reason why we choose FastSpeech2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' As shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  3, based on FastSpeech2, we implement the multi-speaker FastSpeech2 by adding  the speaker encoder module.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The speaker encoder includes speaker embedding,  dense, and softplus layers 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In the network architecture setting, the number of  speakers is 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The dimension of speaker embedding is 384.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The hidden side of  the text encoder is 384 and the number of hidden layers is 4, the hidden layer  size of the decoder is 384 and the number of hidden layers is 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The number  of Conv layers of the variance predictors is 2 and the dropout rate is 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The  initial learning rate is 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='001 and the dropout rate is 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  The HiFi-GAN vocoder builds the network through a generative adversarial  network to converts Mel-spectrogram into high-quality audio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The generator  of HiFi-GAN consists of an upsampling structure, which consists of a one-  dimensional transposed convolution, and a multi-receptive filed fusion module,  3 https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='com/TensorSpeech/TensorFlowTTS  8  Kailin Liang & Bin Liu & Yifan Hu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Character  Embedding  Mongolian Scripts  Text Encoder  Speaker  Encoder  Speaker_id  Positional  Encoding  Variance Adaptor  Positional  Encoding  Mel-spectrogram  Decoder  HiFi-GAN  MRF  (a) Fastspeech2  (b) HiFi-GAN  Speaker  Embedding  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' 3: The structure of the FastSpeech2+HiFi-GAN model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We implement the  multi-speaker FastSpeech2 by adding the speaker encoder module.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  which is responsible for optimizing the upsampling points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' HiFi-GAN, as a  generative adversarial network, has two kinds of discriminators, including multi-  scale and multi-period discriminators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The generagor kernel size of HiFi-GAN is 7  and the upsampling ratio is (8,8,2,2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The list of discriminators for the cycle scale  is (2,3,5,7,11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The Conv filters of each periodic discriminator are 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The pooling  type of output downsampling in the melgan discriminator is AveragePooling1D,  the kernel size is (5,3), and the activation function is LeakyReLU.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' HiFi-GAN is  trained independently of FastSpeech2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' For each speaker, the generator with only  stft loss is first trained for 100k steps, and then the generator and discriminator  are trained for 100k steps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This gives us the corresponding vocoder for each of  the three speakers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Note that a teacher Tacotron2 model trained for each speaker was used  to extract duration from the attention contrast for subsequent FastSpeech2  model training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' For each speaker, the Tacotron2 model trained with 100k steps  of MnTTS was used to extract the duration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' After that, the multi-speaker  FastSpeech2 model was trained with 200k steps to do the final speech generation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  100k steps were trained for HiFi-GAN’s generator and 100k steps for jointly  ku[1] x1 ConvTranspose  stride: ku[1]/2, channels: hu/2]MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset  9  training the generator and discriminator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' All the above models were trained on  2 Tesla V100 GPUs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='2  Naturalness Evaluation  For a full comparison of naturalness, we compared our baseline system,  FastSpeech2+HiFi-GAN with the Ground Truth speech.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In addition, to  verify the performance of HiFi-GAN, we added a FastSpeech2+Griffin-Lim  baseline model for further comparison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The Griffin-Lim algorithm can directly  obtain the phase information of the audio to reconstruct the waveform without  additional training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We used the Naturalness Mean Opinion Score (SS-MOS)  [29] to assess naturalness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' For each speaker, we randomly select 20 sentences  as the evaluation set, which are not used for training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The model-generated  audio and the ground truth audio were randomly disrupted and distributed  to listeners.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' During the evaluation process, 10 native Mongolian speakers were  asked to evaluate the naturalness of the generated 400 audio speeches in a quiet  environment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  The N-MOS results are given in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Ground truth speech gets the  best performance without a doubt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' FastSpeech2+HiFi-GAN outperforms the  FastSpeech2+Griffin-Lim and achieves much closer performance to the ground  truth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Each speaker’s N-MOS score was above 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='0 on the combination of  FastSpeech2 and HiFi-GAN.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Specifically, for the F1, F2, and F3, the N-MOS of FastSpeech2+HiFi-GAN  achieved 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='02, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='15, and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='29 respectively, which is encouraging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' This proves  that high-quality Mongolian speech can be synthesized using MnTTS2 and the  proposed model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In a nutshell, all results prove that our MnTTS2 dataset can  be used to build a robust TTS system for high-quality speech generation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Table 2: Naturalness mean opinion score (N-MOS) results for all systems with  95% Confidence intervals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  System  Speaker ID  F1  F2  F3  FastSpeech2+Griffin-Lim  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='56±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='18  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='59±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='04  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='86±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='12  FastSpeech2+HiFi-GAN  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='02±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='18  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='15±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='06  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='29±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='11  Ground Truth  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='73±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='08  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='70±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='14  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='68±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='09  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='3  Speaker Similarity Evaluation  We further conduct listening experiments to evaluate the speaker similarity  performance for the FastSpeech+HiFi-GAN baseline system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The Speaker  Similarity Mean Opinion Score (SS-MOS) results are reported in Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  We synthesized 20 audios for each speaker by FastSpeech2+HiFi-GAN  baseline system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Ten native Mongolian-speaking volunteers were also invited  10  Kailin Liang & Bin Liu & Yifan Hu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  to participate in the scoring.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Each volunteer needs to evaluate whether the  speaker is the same person or not in the synthesized and the ground truth audio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  The SS-MOS scores for F1, F2, and F3 are 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='58, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='04, and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='12 respectively,  which is encouraging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The results show that the audio synthesized by the  FastSpeech2+HiFi-GAN system performs good performance in terms of speaker  similarity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The highest SS-MOS score was obtained for speaker F1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Auditioning  the audio, we can find that F1’s timbre has significant characteristics and the  synthesized audio represents the speaker’s voice information well.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In a nutshell,  this experiment shows that the MnTTS2 dataset can be used for speech synthesis  work in multi-speaker scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Table  3:  Speaker  Similarity  Mean  opinion  score  (SS-MOS)  results  for  FastSpeech2+HiFi-GAN system with 95% Confidence intervals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  System  Speaker ID  F1  F2  F3  FastSpeech2+HiFi-GAN  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='58±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='21  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='04±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='16  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='12±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='10  5  Challenges and Future Work  With the development of “Empathy AI”, the research of emotional TTS has  attracted more and more attention [30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Speech synthesis in conversational  scenarios and emotional speech synthesis are hot research topics nowadays [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Furthermore, how to control the emotion category and the emotional intensity  during speech generation is an interesting direction [32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' However, our MnTTS2  does not involve information related to emotion category and emotion intensity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  In future work, we will carry out a more comprehensive and in-depth expansion  of the data to serve the development of emotional Mongolian TTS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  6  Conclusion  We presented a large-scale, open-source Mongolian text-to-speech corpus, MnTTS2,  which enriches MnTTS with more durations, topics, and speakers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Releasing  our corpus under the Knowledge Attribution 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='0 International License, the  corpus allows both academic and commercial use.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We describe in detail  the process of building the corpus, while we validate the usability of the  corpus by synthesizing sounds with the FastSpeech2 model and the HiFi-GAN  vocoder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' The experimental results show that our system can achieve satisfactory  performance on the MnTTS2, which indicates that the MnTTS2 corpus is  practically usable and can be used to build robust multi-speaker TTS system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  In future work, we will introduce emotional TTS dataset to further enrich our  corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' We also plan to compare the effects of different TTS architectures and  model hyperparameters on the results and conduct subsequent analyses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset  11  References  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Jonathan Shen, Ruoming Pang, Ron J Weiss, Mike Schuster, Navdeep Jaitly,  Zongheng Yang, Zhifeng Chen, Yu Zhang, Yuxuan Wang, Rj Skerrv-Ryan, et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Natural tts synthesis by conditioning wavenet on mel spectrogram predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  In 2018 IEEE international conference on acoustics, speech and signal processing  (ICASSP), pages 4779–4783.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content=' Charpentier and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Stella.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Diphone synthesis using an overlap-add technique for  speech waveforms concatenation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' In ICASSP ’86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content=' Lawrence R Rabiner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' A tutorial on hidden markov models and selected applications  in speech recognition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content=' Kyunghyun Cho, Bart van Merriënboer, Dzmitry Bahdanau, and Yoshua Bengio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  On the properties of neural machine translation: Encoder–decoder approaches.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Syntax, Semantics and Structure in Statistical Translation, page 103, 2014.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content=' Yuxuan Wang, RJ Skerry-Ryan, Daisy Stanton, Yonghui Wu, Ron J Weiss,  Navdeep Jaitly, Zongheng Yang, Ying Xiao, Zhifeng Chen, Samy Bengio, et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Tacotron: Towards end-to-end speech synthesis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Interspeech 2017, pages  4006–4010, 2017.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+page_content=' Robert C Streijl, Stefan Winkler, and David S Hands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Mean opinion score (mos)  revisited: methods and applications, limitations and alternatives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Multimedia  Systems, 22(2):213–227, 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Rui Liu, Berrak Sisman, Guanglai Gao, and Haizhou Li.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  Decoding knowledge  transfer for neural text-to-speech training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' IEEE/ACM Transactions on Audio,  Speech, and Language Processing, 30:1789–1802, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  MnTTS2: Multi-Speaker Mongolian Text-to-Speech Synthesis Dataset  13  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Rui Liu, Berrak Sisman, and Haizhou Li.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Reinforcement learning for emotional  text-to-speech synthesis with improved emotion discriminability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  In Hynek  Hermansky, Honza Cernocký, Lukás Burget, Lori Lamel, Odette Scharenborg,  and Petr Motlícek, editors, Interspeech 2021, 22nd Annual Conference of the  International Speech Communication Association, Brno, Czechia, 30 August - 3  September 2021, pages 4648–4652.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' ISCA, 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content='  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Rui Liu, Haolin Zuo, De Hu, Guanglai Gao, and Haizhou Li.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
+page_content=' Explicit intensity  control for accented text-to-speech, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/edAyT4oBgHgl3EQfw_kw/content/2301.00657v1.pdf'}
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+LEAST ABSOLUTE DEVIATION ESTIMATION FOR AR(1)
+PROCESSES WITH ROOTS CLOSE TO UNITY
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+Abstract. We establish the asymptotic theory of least absolute deviation
+estimators for AR(1) processes with autoregressive parameter satisfying n(ρn−
+1) → γ for some fixed γ as n → ∞, which is parallel to the results of ordinary
+least squares estimators developed by Andrews and Guggenberger (2008) in
+the case γ = 0 or Chan and Wei (1987) and Phillips (1987) in the case γ ̸= 0.
+Simulation experiments are conducted to confirm the theoretical results and
+to demonstrate the robustness of the least absolute deviation estimation.
+1. Introduction
+Consider the following AR(1) process
+yi = ρyi−1 + ϵi,
+1 ≤ i ≤ n,
+where ρ is a deterministic parameter and {ϵi}i∈Z is a sequence of independent and
+identically distributed (i.i.d.) random variables with mean zero and finite variance.
+The asymptotic properties of the ordinary least squares (OLS) estimator of ρ have
+been extensively studied in the literature; we refer to Anderson (1959), White
+(1958), Dickey and Fuller (1979), Phillips (1987), Chan (2009), Miao and Shen
+(2009), and references therein. To further handle the data that allows for large
+shocks in dynamic structure of the process, e.g. modeling the asset-price bubbles,
+it is usually to require the parameter ρ to depend on the sample size n. On the
+other hand, to understand the phenomena that the unit root test generally has a
+low discriminatory power against the alternative of root close to but not equal to
+unity, Bobkoski (1983) and Cavanagh (1985) introduced a local unit root model
+with the parameter ρ depending on the sample size n and tending to unity as
+n → ∞. Since then, many researchers systematically established the limit theory
+for various near unit root processes.
+See Chan and Wei (1987), Phillips (1987,
+1988), Phillips and Magdalinos (2007), Aue and Horv´ath (2007), Andrews and
+Guggenberger (2008), Buchmann and Chan (2013), Miao et al. (2015), Jiang et
+al. (2022), Tanaka (2017), and references therein. In particular, we refer to Stock
+(1991) for the empirical research or Phillips (2021) for the recent theoretical progress
+and empirical research on the processes with near unit roots.
+Recently, Zhou and Lin (2014) and Wang et al. (2020) studied the statistical
+inference for the autoregressive parameter under the framework of the least absolute
+deviation (LAD) estimation. They proved that, if ρn → 1 and n|ρn − 1| → ∞ as
+n → ∞, then the LAD estimators have normal and Cauchy asymptotic distributions
+under the mildly-stationary case and the mildly-explosive case respectively, which
+Key words and phrases. Asymptotic distribution; autoregressive processes; least absolute de-
+viation estimation; local to unity; unit root test.
+1
+arXiv:2301.02291v1  [math.ST]  5 Jan 2023
+
+2
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+are complementary to the results of the OLS estimators established by Giraitis and
+Phillips (2006) and Phillips and Magdalinos (2007). In fact, the LAD estimator
+was first considered in the study of autoregressive processes in the case that the
+regressive parameters are constants and the innovations have infinite variance due
+to the robust property of LAD estimation. For example, see the papers, Pollard
+(1991), Phillips (1991), Davis et al. (1992), and Li and Li (2009). Specially, Herce
+(1996) studied the asymptotic property of the LAD estimator in a unit root process
+with finite variance innovations and correspondingly developed the unit root test
+in this case which complement similar ones obtained by Knight (1989).
+Motivated by the above work, the goal of the present article is to establish
+the asymptotic theory of LAD estimators for AR(1) processes when the regressive
+parameter satisfies n(ρn −1) → 0 or n(ρn −1) → γ for some fixed γ ̸= 0 as n → ∞.
+To the best of our knowledge, this part of research is still missing although we
+already have a rich literature in LAD estimations and unit root test for AR(1)
+processes. It is shown that, if n(ρn − 1) → 0 as n → ∞, the limiting distributions
+are dominated by the initial conditions both in the near-stationary case and the
+near-explosive case.
+This phenomena have been studied by M¨uller and Elliott
+(2003), Phillips and Magdalinos (2009), and references therein. Our results in the
+near-stationary case correspond exactly to the theory on the OLS estimators for the
+same model developed by Andrews and Guggenberger (2008). With the condition
+n(ρn − 1) → γ for some fixed γ ̸= 0 as n → ∞, we study the asymptotic theory
+of the LAD estimator under the assumption y0 = 0.
+The work in this case is
+complementary to the theory of the OLS estimation developed by Chan and Wei
+(1987) and Phillips (1987).
+This paper is organized as follows. After introducing the model, we state the
+main results in Section 2. Section 3 reports some simulation studies to illustrate
+the finite sample performance and to confirm the asymptotic results. Section 4
+consists of concluding remarks and Section 5 provides the proofs of main results.
+All the other technical proofs are given in Appendix.
+Throughout this paper, the symbols ‘→d’, ‘→p’ and ‘=d’ denote the weak conver-
+gence, convergence in probability and equality in distribution, respectively; op(1)
+means tending to zero in probability; C denotes the standard Cauchy random vari-
+able and N (µ, σ2) denotes the normal random variable with mean µ and variance
+σ2; [x] represents the integral part of x; sign(·) is the signum function; IA is the
+indicator function of set A and det(M) is the determinant of matrix M.
+2. Main results
+Suppose that the data {yi} are generated by the following autoregressive model
+with order one
+yi = ρnyi−1 + ϵi,
+1 ≤ i ≤ n,
+(1)
+where the parameter ρn satisfies ρn → 1 as n → ∞, and the noises {ϵi}i∈Z satisfy
+the following assumptions:
+(i). {ϵi}i∈Z are i.i.d. random variables with mean zero and finite variance σ2;
+(ii). ϵ1 has zero median and a differentiable density function f(x) in R with
+f(0) > 0 and supx∈R |f ′(x)| < ∞.
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+3
+Note that, formally the data {yi} is a triangular array but here n is omitted for
+notational simplicity. With the above assumptions on the noises, one can also study
+the estimation of the parameter ρn with ρn → −1 as n → ∞. For the purpose of
+simplicity, we only state the results for the positive ρn case in this paper.
+The LAD estimator of ρn is defined as a solution of the following extremum
+problem
+ˆρLAD = arg min
+ρ∈R
+�
+1
+n
+n
+�
+i=1
+|yi − ρyi−1|
+�
+.
+(2)
+Notice that, the LAD estimators usually do not have closed forms and are not
+unique if the object function has a flat segment; see, e.g. Herce (1996). Moreover,
+the LAD estimators are robust, especially they are not significantly affected by the
+presence of outliers. This is confirmed by the simulation study in Section 3.
+2.1. The case n(ρn − 1) → 0 as n → ∞. We first consider the case that the
+parameter ρn satisfies n(ρn − 1) → 0 as n → ∞.
+That is, the autoregressive
+parameter ρn is very nearly unity in the sense that ρn is away from unity by
+o(n−1). The following two theorems are the main results in this case. One is for
+the near-stationary case 0 < ρn < 1 and the other is for the near-explosive case
+ρn > 1.
+Theorem 2.1 (The near-stationary case). For model (1) with 0 < ρn < 1 and
+n(ρn − 1) → 0 as n → ∞, assume that y0 depends on the full past of the noise, i.e.
+y0 = �∞
+j=0 ρj
+nϵ−j, then, as n → ∞, we have
+�
+n
+1 − ρ2n
+(ˆρLAD − ρn) →d
+C
+2σf(0)
+(3)
+and
+�
+�
+�
+�
+n
+�
+i=1
+y2
+i−1 (ˆρLAD − ρn) →d N
+�
+0,
+1
+4f 2(0)
+�
+.
+(4)
+Theorem 2.2 (The near-explosive case). For model (1) with ρn > 1 and n(ρn −
+1) → 0 as n → ∞, assume that y0 is an infinitely distant initialization, i.e. y0 =
+�κn
+j=0 ρj
+nϵ−j, with κn/n → ∞ and κn(ρn − 1) → 0 as n → ∞, then, as n → ∞, we
+have
+√nκn (ˆρLAD − ρn) →d
+C
+2σf(0)
+(5)
+and
+�
+�
+�
+�
+n
+�
+i=1
+y2
+i−1 (ˆρLAD − ρn) →d N
+�
+0,
+1
+4f 2(0)
+�
+.
+(6)
+We give some comments on Theorems 2.1 and 2.2.
+Remark 2.1. Since the AR(1) model (1) is causal when 0 < ρn < 1, the initial
+value y0 can be written as a linear combination over the past information in the
+linear process form y0 = �∞
+j=0 ρj
+nϵ−j. In the same case, ρn ∈ (−1, 1), n(ρn −
+1) → 0 and y0 depends on the full past of the noise, Andrews and Guggenberger
+(2008) obtained the limit theorems for the OLS estimators which are similar to
+
+4
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+Theorem 2.1 except for the appearance of f(0) here.
+Furthermore, because the
+limiting distributions of the t-type estimator include f(0) in LAD estimations, in
+practice we use the following density estimator (Silverman, 1986) for statistical
+inference
+ˆfn(0) :=
+1
+nbn
+n
+�
+i=1
+K
+�yi − ˆρLADyi−1
+bn
+�
+,
+where bn is the bandwidth and K(·) is a kernel function, e.g.
+the Gaussian or
+logistic kernel.
+Remark 2.2. As we mentioned previously, Zhou and Lin (2014) and Wang et al.
+(2020) studied the LAD estimations for ρn satisfying n|ρn − 1| → ∞ where the
+initial value y0 = op(|ρn − 1|−1/2) independent of {ϵi, i ≥ 1}. To be explicit, they
+obtained that
+�
+�
+�
+�
+n
+1−ρ2n (ˆρLAD − ρn) →d N
+�
+0,
+1
+4f 2(0)
+�
+��n
+i=1 y2
+i−1 (ˆρLAD − ρn) →d N
+�
+0,
+1
+4f 2(0)
+�
+(7)
+and
+ρn
+n
+ρ2n − 1 (ˆρLAD − ρn) →d
+C
+2σf(0),
+(8)
+for the mildly-stationary case and the mildly-explosive case, respectively.
+Their
+results match the classic results in Phillips and Magdalinos (2007) except for the
+appearance of f(0), just like the usual LAD estimations.
+It is worth pointing out that, here for the very nearly unit root processes, Theorem
+2.1 and Theorem 2.2 show that, in both near-stationary and near-explosive cases,
+the initial value y0 dominates the asymptotic distributions of the LAD estimator
+and the t-type estimator which are Cauchy and normal respectively.
+Moreover,
+since ρn → 1 at a much faster rate than 1/n, for the near-stationary case, by
+Lemma 5.1, the assumption y0 = op(|ρn −1|−1/2) can not hold and the convergence
+rate
+�
+n/(1 − ρ2n) has a larger order than n which enlarges the convergence rate
+spectrum, while, for the near-explosive case, the convergence rate √nκn also has a
+large order than n which is different from that in equation (8).
+2.2. The case n(ρn − 1) → γ as n → ∞. Now we consider the local unit root
+case that the parameter ρn satisfies n(ρn − 1) → γ for some fixed γ ̸= 0 as n → ∞.
+We remark that, unlike the case, ρn ̸= 1 and n(ρn − 1) → 0 as n → ∞, where
+the initial condition entirely dominates the asymptotic distribution of the sample
+variance �n
+i=1 y2
+i−1, in this case, the initial value depending on the past of the noise
+does not affect the analysis methods essentially so we can assume that y0 = 0 for
+simplicity.
+To state the main results, we first introduce some notations. For 1 ≤ i ≤ n, let
+Kn,i :=
+1
+√nρi−1−n
+n
+sign(ϵi)
+and
+Ln,i :=
+1
+√nρn−i
+n
+ϵi,
+and define
+Kn(t) :=
+[nt]
+�
+i=1
+Kn,i
+and
+Ln(t) :=
+[nt]
+�
+i=1
+Ln,i,
+(9)
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+5
+for 0 ≤ t ≤ 1.
+If we further assume that σ2 = 1 and E|ϵ1|2+δ < ∞ for some
+δ > 0, by Lemma 5.3, the process {(Kn(t), Ln(t)), 0 ≤ t ≤ 1} converges weakly to
+a continuous process
+X(t) = (K(t), L(t)),
+0 ≤ t ≤ 1
+(10)
+with independent Gaussian increments, mean vector zero and covariance matrix
+Γ(t) = (γij(t)) :=
+�
+e−2γ
+2γ (e2γt − 1)
+tE|ϵ1|
+tE|ϵ1|
+e2γ
+2γ (1 − e−2γt)
+�
+,
+0 ≤ t ≤ 1.
+(11)
+Theorem 2.3. For model (1), assume that y0 = 0, σ2 = 1, n(ρn − 1) → γ for
+some fixed γ ̸= 0 as n → ∞, and E|ϵ1|2+δ < ∞ for some δ > 0, then, as n → ∞,
+we have
+n(ˆρLAD − ρn) →d
+1
+2f(0) ·
+� 1
+0 L(t) dK(t)
+� 1
+0 e−2γ(1−t)L2(t) dt
+(12)
+and
+�
+�
+�
+�
+n
+�
+i=1
+y2
+i−1 (ˆρLAD − ρn) →d
+1
+2f(0) ·
+� 1
+0 L(t) dK(t)
+�� 1
+0 e−2γ(1−t)L2(t) dt
+.
+(13)
+Remark 2.3. Zhou and Lin (2014) and Wang et al. (2020) worked on the case that
+ρn → 1 and n|ρn−1| → ∞ as n → ∞, where the convergence rate for the asymptotic
+distributions of the LAD estimators has an order in the range (n1/2, n) for the
+mildly-stationary case. Together with the results in Theorem 2.1 and Theorem 2.2,
+we enlarge the convergence rate spectrum in the asymptotic distributions of the
+LAD estimators. The similar relationship between the rate of ρn and the rate in
+the asymptotic distributions was observed for OLS estimators in the literature, see,
+e.g. Chan and Wei (1987), Phillips (1987), Phillips and Magdalinos (2007), and
+Andrews and Guggenberger (2008).
+Remark 2.4. Let
+D(γ) :=
+1
+2f(0) ·
+� 1
+0 L(t) dK(t)
+� 1
+0 e−2γ(1−t)L2(t) dt
+(14)
+and
+L (γ) :=
+1
+2f(0) ·
+� 1
+0 L(t) dK(t)
+�� 1
+0 e−2γ(1−t)L2(t) dt
+.
+(15)
+Notice that D(γ) and L (γ) are continuous families of distributions indexed by the
+parameter γ. Thus, for the case, ρn = 1 + γ/n, by Lemma 5.3, when γ = 0, i.e.
+ρn ≡ 1, we have
+D(0) =
+1
+2f(0) ·
+� 1
+0 W2(t) dW1(t)
+� 1
+0 W 2
+2 (t) dt
+and
+L (0) =
+1
+2f(0) ·
+� 1
+0 W2(t) dW1(t)
+�� 1
+0 W 2
+2 (t) dt
+,
+here W = (W1, W2) is a bivariate Brownian motion with covariance matrix
+Ξ =
+�
+1
+E|ϵ1|
+E|ϵ1|
+1
+�
+.
+
+6
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+These exactly correspond to the main results in Herce (1996), where the author
+discussed the structure of D(0), a combination of a “unit root” distribution and a
+scale mixture of normal distributions, and used it to construct the LAD-based unit
+root tests. In addition, since σ2 = 1, we have E|ϵ1| ≤ 1, hence the matrix Ξ is non-
+negative definite. However, here D(γ) and L (γ) are too complicate to be analyzed
+effectively so we do some simulations to give an overall view on the distributions of
+D(γ) and L (γ) in Section 3 which illustrate how they depend on the parameter γ.
+Finally, we also remark that, from Theorem 1 in Herce (1996), the local unit root
+case has the optimal rate of convergence for the alternative hypothesis, that is, it
+has the same rate as in the unit root case.
+Followed the above remark, there is a natural question, what can we say about
+the distributions of L (γ) as |γ| → ∞? In fact, like the case for the OLS estimators
+in Chan and Wei (1987) and Phillips (1987), we have the following result.
+Theorem 2.4. For model (1), assume that y0 = 0, σ2 = 1, n(ρn − 1) → γ for
+some fixed γ ̸= 0 as n → ∞, and E|ϵ1|2+δ < ∞ for some δ > 0, then we have
+2f(0) · L (γ) →d N (0, 1),
+as |γ| → ∞.
+(16)
+Remark 2.5. Recall from Remark 2.2, Zhou and Lin (2014) and Wang et al.
+(2020) proved that
+2f(0) ·
+�
+�
+�
+�
+n
+�
+i=1
+y2
+i−1 (ˆρLAD − ρn) →d N (0, 1) ,
+(17)
+for the mildly-stationary case, 0 < ρn < 1 and n(1−ρn) → ∞ as n → ∞. Theorem
+2.4 together with Theorem 2.3 yields that, if let n(ρn − 1) → γ first, and then let
+|γ| → ∞, we can also get the asymptotic normal distribution. Moreover, it is worth
+noting that, although Theorem 2.4 holds for γ → ∞ and γ → −∞, the underlying
+reasoning is quite different between these two cases. In fact, for the large negative
+γ’s, ρn can be thought of much less than one so the model (1) can be regarded
+as stationary and then the asymptotic normality holds; for the positive γ, ρn is
+larger than one and the model (1) is explosive, however Theorem 2.4 shows that the
+asymptotic normality is still valid which is different from the mildly-explosive case
+discussed in Zhou and Lin (2014) and Wang et al. (2020), i.e. the equation (8) in
+Remark 2.2.
+3. simulations
+In this section, we work on Monte Carlo simulation to examine the finite sam-
+ple performance of the estimators in our main results.
+For convenience, in all
+experiments, we always suppose that the data are generated by the AR(1) model,
+yi = ρnyi−1 + ϵi with ρn = 1 + γn−β for some γ ∈ R and β ≥ 1. Furthermore,
+we also assume that the innovations are i.i.d. and have N (0, 1) or U(−1, 1) dis-
+tributions.
+Here U(−1, 1) denotes the uniform random variable on the interval
+(−1, 1). To estimate the parameter f(0), we apply the following density estimator
+(Silverman, 1986)
+ˆfn(0) =
+1
+nbn
+n
+�
+i=1
+K
+�yi − ˆρLADyi−1
+bn
+�
+,
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+7
+where K(·) is the Gaussian kernel and the optimal bandwidth bn associated with
+the Matlab function ksdensity(·, 0) is automatically selected from the data.
+Density curves of estimates.
+We first consider the simulations of Theorem
+2.1 and Theorem 2.2. For the near-stationary case, y0 = �∞
+j=0 ρj
+nϵ−j, the true
+parameters are taken to be (γ, β) = (−10, 2) and we denote the normalized esti-
+mator by ˆρs = 2σ ˆfn(0)
+�
+n/(1 − ρ2n)(ˆρLAD − ρn). For the near-explosive case, take
+y0 = �κn
+j=0 ρj
+nϵ−j, (γ, β) = (10, 2), κn = [n1.3], and denote the normalized estimator
+by ˆρe = 2σ ˆfn(0)√nκn(ˆρLAD − ρn). For both cases, denote the t-type estimators by
+Tn := 2 ˆfn(0)
+��n
+i=1 y2
+i−1 (ˆρLAD − ρn). We simulate 3000 replications with sample
+size n = 1000 for each case. Figure 1 shows that the density curves of ˆρs and ˆρe
+are close to that of the standard Cauchy random variable. Figure 2 confirms the
+asymptotic normality of Tn in the near-stationary and near-explosive cases by using
+the Q-Q graphs.
+Next we simulate the limiting distributions, D(γ) and L (γ), defined as in Re-
+mark 2.4. Let β = 1 and suppose that the innovations are standard normal random
+variables so f(0) = 1/
+√
+2π. For D(γ), simulate 1000 replications with sample size
+n = 200 for each case; Figure 3 illustrates the shape of the asymptotic density
+curves of 2f(0)D(γ) for different γ.
+For L (γ), simulate 1000 replications with
+sample size n = 2000 (γ < 0) and n = 1000 (γ > 0) for each case; Figure 4 confirms
+Theorem 2.4, i.e. the asymptotic normality of 2f(0)L (γ) as |γ| → ∞, which also
+demonstrates the difference of the convergence rate between γ → ∞ and γ → −∞.
+−5
+−4
+−3
+−2
+−1
+0
+1
+2
+3
+4
+5
+0
+0.1
+0.2
+0.3
+0.4
+0.5
+0.6
+ 
+ 
+N(0,1)
+U(−1,1)
+Cauchy
+(a) The near-stationary case
+−5
+−4
+−3
+−2
+−1
+0
+1
+2
+3
+4
+5
+0
+0.1
+0.2
+0.3
+0.4
+0.5
+0.6
+ 
+ 
+N(0,1)
+U(−1,1)
+Cauchy
+(b) The near-explosive case
+Figure 1. Density curves of ˆρs and ˆρe with N (0, 1) and U(−1, 1) in-
+novations.
+
+8
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+-4
+-2
+0
+2
+4
+-4
+-3
+-2
+-1
+0
+1
+2
+3
+(a) The near-stationary case
+-4
+-2
+0
+2
+4
+-4
+-3
+-2
+-1
+0
+1
+2
+3
+(b) The near-explosive case
+Figure 2. Q-Q graphs of statistics Tn with N (0, 1) innovation.
+−30
+−20
+−10
+0
+0.0
+0.1
+0.2
+0.3
+0.4
+0.5
+gamma=−1
+gamma=−5
+gamma=−15
+density of standard normal
+(a) The near-stationary case
+−30
+−25
+−20
+−15
+−10
+−5
+0
+5
+0.0
+0.1
+0.2
+0.3
+0.4
+0.5
+gamma=1
+gamma=2
+gamma=3
+density of standard normal
+(b) The near-explosive case
+Figure 3. Asymptotic density curves of 2f(0)D(γ) with N (0, 1) inno-
+vation.
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+9
+−10
+−8
+−6
+−4
+−2
+0
+2
+4
+0.0
+0.1
+0.2
+0.3
+0.4
+0.5
+gamma=−2
+gamma=−20
+gamma=−300
+density of standard normal
+(a) The near-stationary case
+−15
+−10
+−5
+0
+0.0
+0.1
+0.2
+0.3
+0.4
+0.5
+gamma=1
+gamma=5
+gamma=30
+density of standard normal
+(b) The near-explosive case
+Figure 4. Asymptotic density curves of 2f(0)L (γ) with N (0, 1) inno-
+vation.
+Accuracy of Estimators. Andrews and Guggenberger (2008) achieved the as-
+ymptotic theory of OLS estimators for model (1) with n(ρn − 1) → 0 and 0 <
+ρn < 1.
+Here we will compare the accuracy between the estimators ˆρLAD and
+ˆρOLS, where ˆρOLS denotes the OLS estimator of ρn. For the near-stationary case,
+let y0 = �∞
+j=0 ρj
+nϵ−j, β = 1.1, 1.3 and γ = −5, −50. Here we add 10 for each
+randomly selected 5% sample points to construct outliers when generating data. In
+these experiments, we simulate 1000 replications each with sample size n = 200 or
+500 to compare the empirical means (EM), absolute errors (AE) and mean squared
+errors (MSE) of ˆρLAD and ˆρOLS in two cases, with and without outliers. In the
+case without outliers, Table 1 shows that EM is very close to the true value ρn
+and AE and MSE are very small, which verifies the accuracy of LAD estimator for
+very nearly unit root model. The errors (AE and MSE) decrease as the sample
+size n increases. If there are outliers in the data, Table 2 shows that the errors
+(AE and MSE) of OLS estimator are much larger than those of LAD estimator.
+Furthermore, the OLS estimator occasionally produces estimates greater than one.
+Hence it is concluded that ˆρLAD is more robust than ˆρOLS.
+For the near-explosive case, we take κn = [n1.3] in y0 = �κn
+j=0 ρj
+nϵ−j, and let
+β = 1.5, 1.8, γ = 5, 50. The selection of the parameter values here guarantees that
+n(ρn − 1) → 0, κn(1 − ρn) → 0 and κn/n → ∞, as n → ∞. Since the y values from
+different cases have quite different scales, here we add 10 times of the absolute value
+of the maximum for each randomly selected 5% sample points to construct outliers
+when generating data. In these experiments, we simulate 1000 replications each
+with sample size n = 200 or 500 and study the empirical means (EM), absolute
+errors (AE) and mean squared errors (MSE) of ˆρLAD and ˆρOLS in two cases, with
+and without outliers. Table 3 shows that, if there are no outliers in the data, EM
+is very close to the true value ρn and AE and MSE are very small, which verifies
+
+10
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+the accuracy of the LAD estimator and OLS estimator, while, if there are outliers
+in the data, it is clear from Table 4 that ˆρLAD is more robust than ˆρOLS.
+Table 1. AE/EM and MSE of ˆρLAD(ˆρOLS) for near-stationary AR(1)
+processes with N (0, 1), U(−1, 1) noises: no outliers case.
+ϵi
+N(0, 1)
+U(−1, 1)
+β
+γ
+n
+ρn
+AE/EM
+MSE
+AE/EM
+MSE
+1.1
+-50
+200
+0.8528
+0.0097/0.8431
+0.0127
+0.0112/0.8416
+0.0207
+(0.0083/0.8445)
+(0.0083)
+(0.0084/0.8445)
+(0.0077)
+500
+0.9463
+0.0037/0.9426
+0.0017
+0.0049/0.9414
+0.0030
+(0.0034/0.9428)
+(0.0012)
+(0.0036/0.9427)
+(0.0012)
+-5
+200
+0.9853
+0.0046/0.9807
+0.0010
+0.0037/0.9816
+0.0011
+(0.0083/0.9770)
+(0.0019)
+(0.0073/0.9780)
+(0.0016)
+500
+0.9946
+0.0026/0.9920
+0.0002
+0.0025/0.9921
+0.0002
+(0.0033/0.9913)
+(0.0003)
+(0.0029/0.9917)
+(0.0003)
+1.3
+-50
+200
+0.9490
+0.0072/0.9418
+0.0038
+0.0101/0.9389
+0.0059
+(0.0083/0.9407)
+(0.0035)
+(0.0096/0.9394)
+(0.0035)
+500
+0.9845
+0.0028/0.9817
+0.0005
+0.0038/0.9807
+0.0008
+(0.0037/0.9808)
+(0.0005)
+(0.0034/0.9811)
+(0.0005)
+-5
+200
+0.9949
+0.0029/0.9920
+0.0003
+0.0025/0.9924
+0.0004
+(0.0065/0.9884)
+(0.0011)
+(0.0047/0.9890)
+(0.0006)
+500
+0.9985
+0.0018/0.9966
+0.0001
+0.0018/0.9967
+0.0001
+(0.0025/0.9960)
+(0.0001)
+(0.0019/0.9966)
+(0.0001)
+Table 2. AE/EM and MSE of ˆρLAD(ˆρOLS) for near-stationary AR(1)
+processes with N (0, 1), U(−1, 1) noises: outliers case.
+ϵi
+N(0, 1)
+U(−1, 1)
+β
+γ
+n
+ρn
+AE/EM
+MSE
+AE/EM
+MSE
+1.1
+-50
+200
+0.8528
+0.0046/0.8574
+0.0015
+0.0046/0.8574
+0.00009
+(0.0451/0.8979)
+(0.0121)
+(0.0500/0.9028)
+(0.0138)
+500
+0.9463
+0.0039/0.9501
+0.0002
+0.0033/0.9495
+0.0001
+(0.0320/0.9783)
+(0.0052)
+(0.0338/0.9801)
+(0.0058)
+-5
+200
+0.9853
+0.0015/0.9868
+0.0001
+0.0013/0.9866
+0.0000
+(0.0145/0.9998)
+(0.0011)
+(0.0150/1.0003)
+(0.0012)
+500
+0.9946
+0.0007/0.9954
+0.0000
+0.0006/0.9953
+0.0000
+(0.0065/1.0011)
+(0.0002)
+(0.0066/1.0012)
+(0.0002)
+1.3
+-50
+200
+0.9490
+0.0024/0.9514
+0.0004
+0.0029/0.9519
+0.0002
+(0.0297/0.9787)
+(0.0046)
+(0.0320/0.9810)
+(0.0052)
+500
+0.9845
+0.0016/0.9861
+0.0000
+0.0013/0.9858
+0.0000
+(0.0137/0.9982)
+(0.0009)
+(0.0140/0.9985)
+(0.0010)
+-5
+200
+0.9949
+0.0009/0.9958
+0.0000
+0.0011/0.9960
+0.0001
+(0.0091/1.0040)
+(0.0005)
+(0.0095/1.0044)
+(0.0006)
+500
+0.9985
+0.0006/0.9990
+0.0001
+0.0004/0.9989
+0.0001
+(0.0040/1.0024)
+(0.0001)
+(0.0040/1.0025)
+(0.0001)
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+11
+Table 3. AE/EM and MSE of ˆρLAD(ˆρOLS) for near-explosive AR(1)
+processes with N (0, 1), U(−1, 1) noises: no outliers case.
+ϵi
+N(0, 1)
+U(−1, 1)
+β
+γ
+n
+ρn
+AE/EM
+MSE
+AE/EM
+MSE
+1.5
+50
+200
+1.0177
+2.2e-5/1.0177
+2.5e-9
+2.2e-5/1.0177
+2.5e-9
+(2.2e-5/1.0177)
+(2.5e-9)
+(2.2e-5/1.0177)
+(2.5e-9)
+500
+1.0045
+2.8e-5/1.0045
+3.9e-9
+2.8e-5/1.0045
+3.9e-9
+(2.8e-5/1.0045)
+(3.9e-9)
+(2.8e-5/1.0045)
+(3.9e-9)
+5
+200
+1.0018
+-6e-4/1.0012
+4.5e-5
+-8e-4/1.0009
+6.7e-5
+(-e-6/1.0018)
+(e-5)
+(1.8e-4/1.0019)
+(e-5)
+500
+1.0004
+-3.8e-4/1.00007
+1.3e-5
+-5.7e-4/0.9999
+2.8e-5
+(1.2e-4/1.0006)
+(1.5e-6)
+(0.0002/1.0007)
+(e-6)
+1.8
+50
+200
+1.0036
+-1.6e-4/1.0034
+1.4e-5
+-2e-4/1.0034
+1.5e-5
+(-5e-5/1.0036)
+(3e-6)
+(-e-4/1.0035)
+(3.7e-6)
+500
+1.0007
+-2.6e-4/1.0004
+9e-6
+3.7e-4/1.0003
+1.8e-5
+(4e-5/1.0007)
+(e-6)
+(9e-5/1.0008)
+(9e-7)
+5
+200
+1.0004
+-0.0017/0.9986
+e-4
+-0.0020/0.9984
+1.7e-4
+(4e-4/1.0007)
+(1.9e-5)
+(6e-4/1.0010)
+(e-5)
+500
+1.00007
+-9.6e-4/0.9991
+3.9e-5
+-0.0011/0.9989
+5.7e-5
+(3e-4/1.00036)
+(1.6e-6)
+(2.7e-4/1.00035)
+(9e-7)
+Table 4. AE/EM and MSE of ˆρLAD(ˆρOLS) for near-explosive AR(1)
+processes with N (0, 1), U(−1, 1) noises: outliers case.
+ϵi
+N(0, 1)
+U(−1, 1)
+β
+γ
+n
+ρn
+AE/EM
+MSE
+AE/EM
+MSE
+1.5
+50
+200
+1.0177
+-0.0144/1.0033
+0.0020
+-0.0140/1.0037
+0.0019
+(-0.4835/0.5341)
+(2.1195)
+(-0.4703/0.5474)
+(2.0560)
+500
+1.0045
+-7.1e-3/0.9974
+5.1e-4
+-0.0069/0.9976
+5e-4
+(-0.5434/0.4610)
+(1.9600)
+(-0.5345/0.4700)
+(1.9105)
+5
+200
+1.0018
+-0.0080/0.9939
+3.8e-4
+-0.0090/0.9928
+4.6e-4
+(-0.7847/0.2171)
+(3.1892)
+(-0.7748/0.2270)
+(3.1400)
+500
+1.0004
+-0.0064/0.9941
+2.5e-4
+-0.0074/0.9930
+3.2e-4
+(-0.7823/0.2182)
+(3.1841)
+(-0.7731/0.2273)
+(3.1062)
+1.8
+50
+200
+1.0036
+-0.0033/1.0003
+1.2e-4
+-0.0038/0.9998
+1.5e-4
+(-0.7888/0.2148)
+(3.1625)
+(-0.7929/0.2108)
+(3.1825)
+500
+1.0007
+-0.0045/0.9962
+1.5e-4
+-0.0055/0.9952
+2.1e-4
+(-0.7930/0.2077)
+(3.2306)
+(-0.7952/0.2055)
+(3.2533)
+5
+200
+1.0004
+-9.6e-3/0.9907
+4.8e-4
+-9.8e-3/0.9905
+5e-4
+(-0.7404/0.2600)
+(2.9465)
+(-0.7364/0.2640)
+(2.9257)
+500
+1.00007
+-8.4e-3/0.9917
+3.8e-4
+-9.0e-3/0.9911
+4.3e-4
+(-0.7375/0.2625)
+(2.9256)
+(-0.7394/0.2607)
+(2.9476)
+4. Concluding remarks
+In this article we develop the limit theory of the LAD estimator for the AR(1)
+process with a root close to unity. The parameter ρn satisfies n(ρn − 1) → 0 or
+n(ρn −1) → γ for some fixed number γ ̸= 0, as n → ∞. It is shown that, in the first
+case, for both near-stationary and near-explosive processes, the LAD estimator and
+the t-type statistic have Cauchy and normal asymptotic distribution, respectively.
+The simulation study in this case confirms the theoretical results and it illustrates
+that the theory should be useful in statistical inference and the LAD estimator is
+
+12
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+robust if there are outliers in the data. In the case that n(ρn − 1) → γ for some
+fixed number γ ̸= 0, as n → ∞, we also develop asymptotic theory for the LAD
+estimator and the t-type statistic under the assumption that y0 = 0 which gives us
+the connection with the existing results in literature, e.g. Chan and Wei (1987),
+Phillips (1987), and Herce (1996).
+In summary, we establish the asymptotic theory of the LAD estimators for the
+nearly unit root processes which correspond to the results of the OLS estimators
+developed by Chan and Wei (1987), Phillips (1987, 1988, 2021), Phillips and Mag-
+dalinos (2007), Andrews and Guggenberger (2008), Chan (2009) and so on. The
+results in this article are also the completion of the LAD estimators studied in
+Zhou and Lin (2014) and Wang et al. (2020). These authors worked on the case
+that ρn → 1 and n|ρn − 1| → ∞ as n → ∞. The normalizer of the asymptotic
+distributions for the LAD estimators there has a rate in the range (n1/2, n) for
+the near-stationary case. We enlarge the rate spectrum of the normalizer in the
+asymptotic distributions of the LAD estimators.
+5. Proof of main results
+We first give some comments on the proofs. It is known that the methods of
+the LAD estimation are classic which were developed by Pollard (1991), Davis et
+al. (1992), Knight (1989, 1998) and Ling (2005). The limiting behaviors of the
+quadratic functionals, �n
+i=1 y2
+i−1 and �n
+i=1 yi−1sign(ϵi), play the crucial role in the
+analysis. Concretely, for the very nearly case, n(ρn − 1) → 0, we mainly follow
+the strategies of Zhou and Lin (2014) and Wang et al. (2020), while, under our
+framework, the initial values y0 dominate the asymptotic behavior of �n
+i=1 y2
+i−1;
+see Lemma 5.1 and Lemma 5.2. More work is required for the local unit root case,
+n(ρn − 1) → γ for some γ ̸= 0.
+To treat the asymptotic joint distributions of
+� 1
+n
+�n
+i=1 yi−1sign(ϵi), 1
+n2
+�n
+i=1 y2
+i−1
+�
+, we need to develop a functional central limit
+theorem for the process {(Kn(t), Ln(t)), 0 ≤ t ≤ 1} defined as in (9), i.e. Lemma
+5.3, by the vector-value martingale invariance principle. We remark that, although
+Phillips and Durlauf (1986) (Lemma 3.1) established the asymptotic theory for
+sample moments of vector-value integrated processes, their results can not be used
+here because the regression parameter ρn depends on the sample size n which causes
+the covariance matrix defined as in (11) to be time-dependent. Finally, by using the
+tools from stochastic calculus, we achieve the estimates, Lemma 5.4 and Lemma
+5.5, which is the key of the proof in Theorem 2.4.
+Throughout the proof, we use the following identity of Knight (1998),
+for x ̸= 0,
+|x − y| − |x| = −ysign(x) + 2
+� y
+0
+�
+I{x≤s} − I{x≤0}
+�
+ds.
+(18)
+From the model (1), we also observe that
+yi = ρi
+ny0 +
+i
+�
+j=1
+ρi−j
+n
+ϵj,
+1 ≤ i ≤ n.
+(19)
+5.1. The case n(ρn−1) → 0 as n → ∞. In this subsection, we will prove Theorem
+2.1 and Theorem 2.2. Let us start by presenting two lemmas proved in Appendix.
+Lemma 5.1. Under the assumptions of Theorem 2.1, we have
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+13
+(1).
+�
+1 − ρ2ny0 →d σX;
+(2).
+1
+√n
+�n
+i=1 ρi−1
+n
+sign(ϵi) →d Y ;
+(3).
+�
+(1 − ρ2n)/n max1≤i≤n |yi−1| →p 0;
+here X and Y are independent standard normal random variables.
+Lemma 5.2. Under the assumptions of Theorem 2.2, we have
+(1).
+1
+√κn y0 →d σU;
+(2).
+1
+√n
+�n
+i=1 ρi−1
+n
+sign(ϵi) →d V ;
+(3).
+1
+√nκn max1≤i≤n |yi−1| →p 0;
+here U and V are independent standard normal random variables.
+Proof of Theorem 2.1. Denote ˆun =
+�
+n/(1 − ρ2n)(ˆρLAD − ρn). Then ˆun is the
+minimizer of the following convex objective function,
+Zn(u) =
+n
+�
+i=1
+�
+|ϵi −
+�
+(1 − ρ2n)/nyi−1u| − |ϵi|
+�
+.
+Based on the ideas of Davis et al. (1992) and Ling (2005), if we can prove that, for
+each u, Zn(u) converges weakly to a random variable which has a unique minimizer
+umin, then ˆun must converge weakly to umin.
+By (18), we rewrite Zn(u) as follows
+Zn(u) = −uAn + 2
+n
+�
+i=1
+ξi(u),
+(20)
+here
+An =
+�
+(1 − ρ2n)/n
+n
+�
+i=1
+yi−1sign(ϵi)
+and
+ξi(u) =
+� √
+(1−ρ2
+n)/nyi−1u
+0
+�
+I{ϵi≤s} − I{ϵi≤0}
+�
+ds.
+Next we analyze the asymptotic properties of An and ξi(u), respectively. By (19),
+we can decompose An as follows
+An =
+�
+(1 − ρ2n)/n
+n
+�
+i=1
+�
+ρi−1
+n
+y0 +
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj
+�
+sign(ϵi)
+=
+�
+(1 − ρ2n)y0 ·
+1
+√n
+n
+�
+i=1
+ρi−1
+n
+sign(ϵi) + Rn,1,
+(21)
+where the remainder
+Rn,1 =
+�
+(1 − ρ2n)/n
+n
+�
+i=1
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj sign(ϵi).
+The parts (1) and (2) of Lemma 5.1, together with the continuous mapping theorem,
+yield that the first term in the equation (21) converges weakly to the random
+variable σXY , where X and Y are independent standard normal random variables.
+
+14
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+Now, we show that the remainder converges to zero in probability. Obviously, by
+simple calculations, E(Rn,1) = 0 and
+E(R2
+n,1) = 1 − ρ2
+n
+n
+E
+��
+n
+�
+i=1
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj sign(ϵi)
+�2�
+= 1 − ρ2
+n
+n
+n
+�
+i=1
+E
+�� i−1
+�
+j=1
+ρi−1−j
+n
+ϵj
+�2�
+= n − 1
+n
+�
+1 −
+ρ2
+n − ρ2n
+n
+(n − 1)(1 − ρ2n)
+�
+σ2 → 0
+as n → ∞, where the last step is due to Proposition A.1.
+Consequently, An
+converges weakly to the random variable σXY .
+We now analyze the second term �n
+i=1 ξi(u) in the equation (20) by the mar-
+tingale method. Denote the filtration by Fn,i = σ(y0, ϵ1, . . . , ϵi) for 1 ≤ i ≤ n and
+n ≥ 1, then we can write
+n
+�
+i=1
+ξi(u) =
+n
+�
+i=1
+E(ξi(u)|Fn,i−1) + Rn,2,
+where the remainder
+Rn,2 =
+n
+�
+i=1
+(ξi(u) − E(ξi(u)|Fn,i−1)).
+is a martingale with respect to the filtration, {Fn,i, 1 ≤ i ≤ n}.
+By the Taylor’s formula,
+n
+�
+i=1
+E(ξi(u)|Fn,i−1) =
+n
+�
+i=1
+� √
+(1−ρ2n)/nyi−1u
+0
+E
+�
+I{ϵi≤s} − I{ϵi≤0}
+�
+ds
+=
+n
+�
+i=1
+� √
+(1−ρ2n)/nyi−1u
+0
+(F(s) − F(0)) ds
+=
+n
+�
+i=1
+� √
+(1−ρ2n)/nyi−1u
+0
+�
+f(0)s + 1
+2f ′(s∗)s2�
+ds
+= u2f(0)
+2
+· 1 − ρ2
+n
+n
+n
+�
+i=1
+y2
+i−1 + Rn,3,
+(22)
+where F(·) is the distribution function of ϵ1, s∗ ∈ (0, s) and the remainder
+Rn,3 = 1
+2
+n
+�
+i=1
+� √
+(1−ρ2n)/nyi−1u
+0
+f ′(s∗)s2ds.
+We first consider the sample variance, �n
+i=1 y2
+i−1. From equation (19),
+n
+�
+i=1
+y2
+i−1 =
+n
+�
+i=1
+ρ2(i−1)
+n
+y2
+0 +
+n
+�
+i=1
+ρi−1
+n
+i−1
+�
+j=1
+ρi−j−1
+n
+ϵjy0 +
+n
+�
+i=1
+� i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+�2
+.
+(23)
+Simple calculations yield that
+E
+�
+n
+�
+i=1
+� i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+�2�
+=
+n
+�
+i=1
+i−1
+�
+j=1
+ρ2(i−1−j)
+n
+σ2 = (n − 1)σ2
+1 − ρ2n
+�
+1 −
+ρ2
+n − ρ2n
+n
+(n − 1)(1 − ρ2n)
+�
+.
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+15
+Note that, by the Cauchy-Schwarz’s inequality,
+���
+n
+�
+i=1
+ρi−1
+n
+i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+���
+2
+≤
+n
+�
+i=1
+ρ2(i−1)
+n
+n
+�
+i=1
+� i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+�2
+,
+so, applying Proposition A.1 for kn = n and part (1) of Lemma 5.1, for the second
+term in (23), we can obtain
+1 − ρ2
+n
+n
+n
+�
+i=1
+ρi−1
+n
+i−1
+�
+j=1
+ρi−j−1
+n
+ϵjy0 →p 0.
+It also follows, for the third term in (23),
+1 − ρ2
+n
+n
+n
+�
+i=1
+� i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+�2
+→p 0.
+Moreover, Proposition A.1 and part (1) of Lemma 5.1, combined with the contin-
+uous mapping theorem, imply that
+1 − ρ2
+n
+n
+n
+�
+i=1
+ρ2(i−1)
+n
+y2
+0 →d σ2X2.
+Therefore, we have shown that
+1 − ρ2
+n
+n
+n
+�
+i=1
+y2
+i−1 →d σ2X2.
+(24)
+It remains to deal with the remainders, Rn,2 and Rn,3. Notice that
+|Rn,3| ≤ |u|3 supx∈R |f ′(x)|
+3
+�1 − ρ2
+n
+n
+�3/2
+n
+�
+i=1
+|yi−1|3
+≤ |u|3 supx∈R |f ′(x)|
+3
+�1 − ρ2
+n
+n
+�3/2
+max
+1≤i≤n |yi−1|
+n
+�
+i=1
+y2
+i−1,
+by equation (24) and part (3) of Lemma 5.1, Rn,3 converges to zero in probability.
+Since Rn,2 is a martingale, with the methods of Wang et al. (2020) or Zhou and
+Lin (2014) and the help of Lemma 5.1, we can prove that Rn,2 converges to zero in
+probability.
+Summarizing above discussions, we get that
+Zn(u) = −uAn + 2
+n
+�
+i=1
+ξi(u)
+= −u
+�
+(1 − ρ2n)y0 ·
+1
+√n
+n
+�
+i=1
+ρi−1
+n
+sign(ϵi) + u2f(0)1 − ρ2
+n
+n
+n
+�
+i=1
+ρ2(i−1)
+n
+y2
+0 + op(1)
+→d −uσXY + u2σ2f(0)X2 =: Z(u).
+Because Z(u) has a unique minimum at
+umin = Y/(2σf(0)X),
+
+16
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+by Lemma 2.2 of Davis et al. (1992), we derive that
+ˆun =
+�
+n/(1 − ρ2n)(ˆρLAD − ρn) →d
+1
+2σf(0)C.
+Combining this with equation (24) and using the continuous mapping theorem, we
+complete the proof of Theorem 2.1.
+□
+Proof of Theorem 2.2. The proof is similar to that of Theorem 2.1. In this case,
+ˆun = √nκn(ˆρLAD − ρn), Zn(u) = �n
+i=1
+�
+|ϵi − (nκn)−1/2yi−1u| − |ϵi|
+�
+, and in (20),
+An =
+1
+√nκn
+n
+�
+i=1
+yi−1sign(ϵi)
+and
+ξi(u) =
+� yi−1u/√nκn
+0
+�
+I{ϵi≤s} − I{ϵi≤0}
+�
+ds.
+Lemma 5.2 is applied to prove the corresponding terms as in the proof of Theorem
+2.1. Here we only partially demonstrate the role of the assumptions, κn/n → ∞
+and κn(ρn − 1) → 0 as n → ∞. Let us consider the normalized sample variance.
+For the third term of (23), we want to show that
+1
+nκn
+n
+�
+i=1
+� i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+�2
+→p 0.
+By a simple calculation, we get
+E
+�
+n
+�
+i=1
+� i−1
+�
+j=1
+ρi−j−1
+n
+ϵj
+�2�
+=
+n
+�
+i=1
+i−1
+�
+j=1
+ρ2(i−1−j)
+n
+σ2 = (n − 1)σ2
+1 − ρ2n
+�
+1 −
+ρ2
+n − ρ2n
+n
+(n − 1)(1 − ρ2n)
+�
+.
+Then, Proposition A.1 yields that
+1
+nκn
+· (n − 1)σ2
+1 − ρ2n
+�
+1 −
+ρ2
+n − ρ2n
+n
+(n − 1)(1 − ρ2n)
+�
+= O
+� n
+κn
+�
+,
+which tends to zero if κn/n → ∞ as n → ∞. The proof is complete.
+□
+5.2. The case n(ρn−1) → γ as n → ∞. In this subsection, we will prove Theorem
+2.3 and Theorem 2.4.
+Firstly, we prove Theorem 2.3 following the line as in the proofs of the case
+n(ρn − 1) → 0. In this case, ˆun = n(ˆρLAD − ρn) and it is the minimizer of the
+following convex function,
+Zn(u) =
+n
+�
+i=1
+�
+|ϵi − n−1yi−1u| − |ϵi|
+�
+.
+(25)
+Again by the Knight’s identity (18), we can rewrite the quantity Zn(u) in (25) as
+identity (20) with
+An = 1
+n
+n
+�
+i=1
+yi−1sign(ϵi)
+(26)
+and
+ξi(u) =
+� n−1yi−1u
+0
+�
+I{ϵi≤s} − I{ϵi≤0}
+�
+ds.
+(27)
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+17
+Again we use the filtration Fn,i = σ(y0, ϵ1, . . . , ϵi) for 1 ≤ i ≤ n and n ≥ 1, and
+write
+n
+�
+i=1
+ξi(u) =
+n
+�
+i=1
+E(ξi(u)|Fn,i−1) + Rn,1,
+where
+Rn,1 =
+n
+�
+i=1
+(ξi(u) − E(ξi(u)|Fn,i−1))
+(28)
+is a martingale with respect to the filtration, {Fn,i, 1 ≤ i ≤ n}.
+By the same
+argument as in (22),
+n
+�
+i=1
+E(ξi(u)|Fn,i−1) = u2f(0)
+2
+· 1
+n2
+n
+�
+i=1
+y2
+i−1 + Rn,2,
+where
+Rn,2 = 1
+2
+n
+�
+i=1
+� n−1yi−1u
+0
+f ′(s∗)s2ds
+(29)
+and s∗ is between 0 and s. As in the proofs of Theorem 2.1 and Theorem 2.2, to
+obtain the asymptotic distribution of Zn(u), the key point is to analyze the joint
+distribution of
+� 1
+n
+�n
+i=1 yi−1sign(ϵi), 1
+n2
+�n
+i=1 y2
+i−1
+�
+.
+Lemma 5.3. Under the assumptions of Theorem 2.3, the process (Kn(t), Ln(t), 0 ≤
+t ≤ 1) defined as in (9) converges weakly to the continuous process (X(t), 0 ≤ t ≤ 1)
+defined as in (10) with independent Gaussian increments, mean vector zero and
+covariance matrix Γ(t) defined as in (11). Moreover, we also have
+XT(t) =
+� t
+0
+Λ1/2(s) dBT(h(s)),
+0 ≤ t ≤ 1,
+(30)
+where Λ(·) is a non-negative definite matrix-valued function given by
+Λ(t) = (λij(t)) := 1
+2
+� 1 − tanh(2γ(1 − t))
+E| ϵ1|sech(2γ(1 − t))
+E| ϵ1|sech(2γ(1 − t))
+1 + tanh(2γ(1 − t))
+�
+,
+0 ≤ t ≤ 1,
+B = (B1, B2) is a 2-dimensional standard Brownian motion and
+h(t) = 1
+γ
+�
+sinh(2γ) − sinh(2γ(1 − t))
+�
+,
+0 ≤ t ≤ 1.
+Proposition 5.1. Under the assumptions of Theorem 2.3, as n → ∞,
+�
+1
+n
+n
+�
+i=1
+yi−1sign(ϵi), 1
+n2
+n
+�
+i=1
+y2
+i−1
+�
+→d
+�� 1
+0
+L(t) dK(t),
+� 1
+0
+e−2γ(1−t)L2(t) dt
+�
+.
+Proof. Observe that
+1
+n
+n
+�
+i=1
+yi−1sign(ϵi) =
+n
+�
+i=1
+�
+� 1
+√n
+i−1
+�
+j=1
+ρn−j
+n
+ϵj
+�
+� 1
+√nρi−1−n
+n
+sign(ϵi)
+=
+� 1
+0
+Ln(t) dKn(t)
+
+18
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+and
+1
+n2
+n
+�
+i=1
+y2
+i−1 =
+n
+�
+i=1
+1
+n
+�
+� 1
+√n
+i
+�
+j=1
+ρi−j
+n
+ϵj
+�
+�
+2
+=
+� 1
+0
+e−2γ(1−t)L2
+n(t) dt + Rn,3,
+where the remainder
+Rn,3 = 1
+n
+n
+�
+i=1
+ρ2(i−n)
+n
+L2
+n
+� i
+n
+�
+−
+� 1
+0
+e−2γ(1−t)L2
+n(t) dt.
+According to the same argument in the proof of Lemma 2.2 in Chan and Wei (1987),
+we can show that Rn,3 →p 0 as n → ∞. Hence Theorem 2.1 in Hansen (1992) and
+Lemma 5.3 immediately yield the desired result.
+□
+Proof of Theorem 2.3. Recall the analysis in the beginning of this subsection.
+Notice that Rn,2 in (29) satisfies
+2|Rn,2| ≤ |u|3 supx∈R |f ′(x)|
+3
+1
+n3
+n
+�
+i=1
+|yi−1|3
+≤ |u|3 supx∈R |f ′(x)|
+3
+1
+n max
+1≤i≤n |yi−1| · 1
+n2
+n
+�
+i=1
+y2
+i−1.
+(31)
+By Proposition 5.1 and Proposition A.2, Rn,2 converges to zero in probability. In
+addition, following the same line of Wang et al. (2020) or Zhou and Lin (2014), we
+can also show that Rn,1 in (28) converges to zero in probability. Combining with
+Proposition 5.1, we have
+Zn(u) = −uAn + 2
+n
+�
+i=1
+ξi(u)
+→d −u
+� 1
+0
+L(t) dK(t) + u2f(0)
+� 1
+0
+e−2γ(1−t)L2(t) dt =: Z(u).
+Because Z(u) has a unique minimum at
+umin =
+1
+2f(0) ·
+� 1
+0 L(t) dK(t)
+� 1
+0 e−2γ(1−t)L2(t) dt
+,
+by Lemma 2.2 of Davis et al. (1992),
+ˆun = n(ˆρLAD − ρn) →d
+1
+2f(0) ·
+� 1
+0 L(t) dK(t)
+� 1
+0 e−2γ(1−t)L2(t) dt
+,
+as n → ∞. Applying the continuous mapping theorem and Proposition 5.1 again,
+we complete the proof of Theorem 2.3.
+□
+Proof of Theorem 2.4. Denote the square root of the matrix-valued function
+Λ(t) defined as in Lemma 5.3 by
+Λ1/2(t) =
+�
+�λ11(t)
+�λ12(t)
+�λ12(t)
+�λ22(t)
+�
+,
+0 ≤ t ≤ 1.
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+19
+Then, from Lemma 5.3, we know that
+�
+dK(t) = �λ11(t)dB1(h(t)) + �λ12(t)dB2(h(t))
+dL(t) = �λ12(t)dB1(h(t)) + �λ22(t)dB2(h(t))
+.
+(32)
+Moreover, by the time change for Itˆo integrals, e.g. Theorem 8.5.7 in Øksendal
+(2005), we can rewrite equations (32) as
+�
+dK(t) = �λ11(t)
+�
+h′(t)d �B1(t) + �λ12(t)
+�
+h′(t)d �B2(t)
+dL(t) = �λ12(t)
+�
+h′(t)d �B1(t) + �λ22(t)
+�
+h′(t)d �B2(t)
+,
+(33)
+here �B = ( �B1, �B2) is also a 2-dimensional standard Brownian motion. If denote
+d �B(t) =
+�λ11(t)
+�
+h′(t)d �B1(t) + �λ12(t)
+�
+h′(t)d �B2(t)
+�
+�λ2
+11(t)h′(t) + �λ2
+12(t)h′(t)
+,
+then, by the L´evy characterization of Brownian motion, e.g.
+Theorem 8.6.1 in
+Øksendal (2005), we know that �B is a 1-dimensional standard Brownian motion.
+Notice that
+�λ2
+11(t)h′(t) + �λ2
+12(t)h′(t) = e−2γ(1−t),
+0 ≤ t ≤ 1,
+hence the random variable L (γ) can be represented as
+2f(0) · L (γ) =
+� 1
+0 e−γ(1−t)L(t) d �B(t)
+�� 1
+0 e−2γ(1−t)L2(t) dt
+.
+Now, the subsequent proof will base on Theorem 1 of Rootz´en (1980) which is
+restated as Theorem A.2 in Appendix. We need verify the assumptions in Theorem
+A.2. Let
+ϕγ(t) = 2γe−γe−γ(1−t)L(t),
+0 ≤ t ≤ 1, γ > 0,
+and
+ψγ(t) =
+�
+−2γe−γ(1−t)L(t),
+0 ≤ t ≤ 1, γ < 0,
+then we have the following lemmas whose proofs are postponed to Appendix.
+Lemma 5.4. As γ → ∞,
+sup
+0≤t≤1
+����
+� t
+0
+ϕγ(s) ds
+���� →p 0
+(34)
+and
+� 1
+0
+ϕ2
+γ(t) dt →p N 2(0, 1).
+(35)
+Lemma 5.5. As γ → −∞,
+sup
+0≤t≤1
+����
+� t
+0
+ψγ(s) ds
+���� →p 0
+(36)
+and
+� 1
+0
+ψ2
+γ(t) dt →p 1.
+(37)
+With the help of Lemma 5.4, Lemma 5.5, and Theorem A.2, we complete the
+proof of Theorem 2.4.
+□
+
+20
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+Technical appendix and proofs
+Proposition A.1. Let {kn, n ≥ 1} be a sequence of positive numbers such that
+kn → ∞ and kn|1 − ρ2
+n| → 0 as n → ∞, then we have ρ2kn
+n
+→ 1 and
+1 − ρ2kn
+n
+kn(1 − ρ2n) = 1 + O(kn(1 − ρ2
+n))
+(38)
+as n → ∞.
+Proof. Applying the Taylor’s formula, we have
+log(ρ2kn
+n
+) = kn log(1 + ρ2
+n − 1)
+= kn
+�
+ρ2
+n − 1 − (ρ2
+n − 1)2
+2
++ . . .
+�
+.
+So ρ2kn
+n
+→ 1. Moreover, using the Taylor’s formula again, we obtain, as n → ∞
+ρ2kn
+n
+= exp{kn(ρ2
+n − 1) + O(kn(ρ2
+n − 1)2)}
+= 1 + kn(ρ2
+n − 1) + O(k2
+n(ρ2
+n − 1)2).
+Thus the estimation (38) follows.
+□
+Proposition A.2. For model (1), assume that y0 = 0 and n(ρn −1) → γ for some
+fixed γ ̸= 0 as n → ∞, then we have
+1
+n max
+1≤i≤n |yi−1| →p 0, as n → ∞.
+Proof. For any ε > 0, by the Kolmogorov’s maximal inequality,
+P
+� 1
+n max
+1≤i≤n |yi−1| > ε
+�
+= P
+�
+max
+1≤i≤n
+��
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj
+�� > nε
+�
+≤
+σ2
+n2ε2 ·
+n−1
+�
+j=1
+ρ2(n−1−j)
+n
+= σ2(ρ2(n−1)
+n
+− 1)
+n2ε2(ρ2n − 1)
+→ 0,
+as n → ∞, which implies the desired result immediately. Here we used the facts,
+n(ρn − 1) → γ and ρn
+n → eγ as n → ∞.
+□
+Proof of Lemma 5.1. (1).
+Note that there exists a sequence mn such that
+mn(1 − ρn) → ∞ as n → ∞, which implies that ρmn
+n
+= o(1). So we can rewrite
+�
+1 − ρ2ny0 as follows
+�
+1 − ρ2ny0 =
+�
+1 − ρ2n
+∞
+�
+j=0
+ρj
+nϵ−j
+=
+�
+1 − ρ2n
+mn
+�
+j=0
+ρj
+nϵ−j +
+�
+1 − ρ2n
+∞
+�
+j=mn+1
+ρj
+nϵ−j
+=: Γn,1 + Γn,2.
+Obviously, E(Γn,2) = 0 and
+E(Γ2
+n,2) = ρ2(mn+1)
+n
+σ2 = o(1),
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+21
+which immediately yield that Γn,2 →p 0 as n → ∞. We apply the Lindeberg-Feller
+central limit theorem for the first term Γn,1. Denote ζn,j =
+�
+1 − ρ2nρj
+nϵ−j, then
+E(Γn,1) = 0 and
+E(Γ2
+n,1) = (1 − ρ2(mn+1)
+n
+)σ2 → σ2
+as n → ∞. Hence, to complete the proof, we verify the Lindeberg condition,
+for any ε > 0,
+mn
+�
+j=0
+E
+�
+ζ2
+n,jI{|ζn,j|>ε}
+�
+= o(1).
+In fact, since 0 < ρn < 1, by dominated convergence theorem, we have
+mn
+�
+j=0
+E
+�
+ζ2
+n,jI{|ζn,j|>ε}
+�
+= (1 − ρ2
+n)
+mn
+�
+j=0
+ρ2j
+n E
+�
+ϵ2
+−jI{|ζn,j|>ε}
+�
+≤ (1 − ρ2
+n)
+mn
+�
+j=0
+ρ2j
+n E
+�
+ϵ2
+−jI{√
+1−ρ2n|ϵ−j|>ε}
+�
+= (1 − ρ2(mn+1)
+n
+)E
+�
+ϵ2
+1I{√
+1−ρ2n|ϵ1|>ε}
+�
+= o(1).
+(2).
+Because the Lindeberg’s condition holds obviously in this case, we only
+need to estimate the asymptotic variance. Noticing that ϵt have zero median, we
+get E(sign(ϵt)) = 0 and
+E
+�� 1
+√n
+n
+�
+i=1
+ρi−1
+n
+sign(ϵi)
+�2�
+=
+1 − ρ2n
+n
+n(1 − ρ2n) → 1
+as n → ∞, here we use the facts, (1 − ρn
+n) ∼ n(1 − ρn) and ρn
+n → 1 as n → ∞.
+(3). Since
+max
+1≤i≤n |yi−1| ≤ max
+�
+|y0|, max
+2≤i≤n |yi−1|
+�
+and
+max
+2≤i≤n |yi−1| ≤ max
+2≤i≤n |ρi−1
+n
+y0| + max
+2≤i≤n
+��
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj
+��,
+part (1) of this lemma implies that
+�
+(1 − ρ2n)/n max
+2≤i≤n |yi−1| ≤
+�
+(1 − ρ2n)/n max
+2≤i≤n
+��
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj
+�� + op(1).
+By the Kolmogorov’s maximal inequality and Proposition A.1, it follows that, for
+any ε > 0,
+P
+��
+(1 − ρ2n)/n max
+2≤i≤n
+��
+i−1
+�
+j=1
+ρi−1−j
+n
+ϵj
+�� > ε
+�
+= P
+��
+(1 − ρ2n)/n max
+2≤i≤n
+��
+i−1
+�
+j=1
+ρj−1
+n
+ϵi−j
+�� > ε
+�
+≤ σ2
+ε2 · 1 − ρ2n
+n
+n
+= σ2
+ε2 ·
+1 − ρ2n
+n
+n(1 − ρn) · (1 − ρn) = o(1),
+which complete the proof of part (3).
+□
+
+22
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+Proof of Lemma 5.2. Noting that κn(1−ρn) → 0 and applying Proposition A.1,
+we can show that, (1 − ρκn
+n ) ∼ κn(1 − ρn) and ρκn
+n
+→ 1 as n → ∞. We omit the
+remainder of the argument since it is analogous to that in the proof of Lemma
+5.1.
+□
+Proposition 5.1 are required to achieve Theorem 2.3 and 2.4. So, in the rest of
+this section, we mainly make the supplement for the proofs in Section 5. First of
+all, we need the following modified version of Theorem 1.4 in Chapter 7 of Ethier
+and Kurtz (1986).
+Theorem A.1 (Ethier and Kurtz, 1986) Let Γ(t) = (γij(t))d
+i,j=1 be a continuous,
+symmetric, d × d matrix-valued function, defined on [0, 1], satisfying Γ(0) = 0 and
+for any 0 ≤ s < t ≤ 1,
+d
+�
+i,j=1
+�
+γij(t) − γij(s)
+�
+αiαj ≥ 0,
+∀ α = (α1, . . . , αd) ∈ Rd.
+Let {ξn
+k , Fn
+k , n ≥ 1, 1 ≤ k ≤ n} be an Rd-valued square-integrable martingale dif-
+ference array on a completed probability space (Ω, F, P). Denote Sn(t) = �[nt]
+k=1 ξn
+k
+and
+Θn(t) =
+�
+θij
+n (t)
+�d
+i,j=1 =
+[nt]
+�
+k=1
+E
+�
+(ξn
+k )Tξn
+k |Fn
+k−1
+�
+,
+for 0 ≤ t ≤ 1. Suppose that,
+E
+�
+sup
+0≤t≤1
+|Sn(t) − Sn(t−)|2�
+→ 0,
+as n → ∞,
+(39)
+and for i, j = 1, 2, . . . , d,
+E
+�
+sup
+0≤t≤1
+|θij
+n (t) − θij
+n (t−)|
+�
+→ 0,
+as n → ∞.
+(40)
+In addition, if, for each 0 ≤ t ≤ 1 and i, j = 1, 2, . . . , d,
+θij
+n (t) →p γij(t),
+as n → ∞,
+(41)
+then the process Sn converges weakly to a continuous process G with independent
+Gaussian increments, mean vector zero and covariance matrix Γ(t), on the Skorohod
+space DRd([0, 1]) of Rd-valued cadlag paths on [0, 1].
+Proof of Lemma 5.3. Recall that, Fi = Fn,i = σ(ϵ1, . . . , ϵi) and F0 = {∅, Ω}.
+For convenience, denote Xn,i = (Kn,i, Ln,i) and Xn(t) = �[nt]
+i=1 Xn,i for 0 ≤ t ≤ 1,
+then it is clear that {Xn,i, Fi} is an R2-valued square-integral martingale difference
+array. Note that, under these circumstances,
+Θn(t) =
+n
+�
+i=1
+E
+�
+XT
+n,iXn,i|Fi−1
+�
+=
+n
+�
+i=1
+E
+�
+XT
+n,iXn,i
+�
+.
+To apply Theorem A.1, we first verify the non-negative definiteness of the matrix-
+valued function Γ(t) defined as in (11). Clearly, for 0 ≤ s < t ≤ 1, the first principle
+minor of Γ(t) − Γ(s) is positive for any γ ̸= 0; moreover, since σ2 = 1, we know
+that E|ϵ1| ≤ 1 and it follows that
+det(Γ(t) − Γ(s)) =
+1
+4γ2
+�
+eγ(t−s) − e−γ(t−s)�2 −
+�
+(t − s)E|ϵ1|
+�2 ≥ 0.
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+23
+So the matrix-valued function Γ(t) is non-negative definite.
+Now, we check the condition (39), i.e.
+E
+�
+max
+1≤i≤n |Xn,i|2�
+→ 0,
+(42)
+as n → ∞. Obviously, since ρn
+n → eγ as n → ∞, we know that
+max
+1≤i≤n |Xn,i|2 ≤ C1
+n
+�
+1 ∨ max
+1≤i≤n ϵ2
+i
+�
+,
+for some positive constant C1 independent of n. For any ε > 0, by the Chebyshev’s
+inequality, we can get
+P( max
+1≤i≤n ϵ2
+i > nε) ≤ nP(ϵ2
+1 > nε)
+≤ ε−(2+δ)/2n−δ/2 · E|ϵ1|2+δ → 0,
+as n → ∞. So
+max
+1≤i≤n |Xn,i|2 →p 0.
+(43)
+On the other hand, notice that, for each n,
+E
+��max1≤i≤n ϵ2
+i
+n
+�(2+δ)/2�
+≤ E|ϵ1|2+δ
+nδ/2
+.
+Hence the family of random variables, {max1≤i≤n |Xn,i|2, n ≥ 1}, is uniformly
+integrable, which, combined with (43), suggests that the condition (42) holds.
+We next calculate the covariance matrix. Observe that
+[nt]
+�
+i=1
+E
+�
+XT
+n,iXn,i
+�
+=
+�
+1
+n
+�[nt]
+i=1 ρ2(i−1−n)
+n
+tρ−1
+n E|ϵ1|
+tρ−1
+n E|ϵ1|
+1
+n
+�[nt]
+i=1 ρ2(n−i)
+n
+�
+.
+Therefore it is straightforward to show that, as n → ∞,
+sup
+0≤t≤1
+|θ11
+n (t) − θ11
+n (t−)| = 1
+n max
+1≤i≤n ρ2(i−1−n)
+n
+→ 0,
+sup
+0≤t≤1
+|θ22
+n (t) − θ22
+n (t−)| = 1
+n max
+1≤i≤n ρ2(n−i)
+n
+→ 0,
+sup
+0≤t≤1
+|θ12
+n (t) − θ12
+n (t−)| = sup
+0≤t≤1
+|θ21
+n (t) − θ21
+n (t−)| = 0,
+and
+Θn(t) → Γ(t) =
+�
+e−2γ
+2γ (e2γt − 1)
+tE|ϵ1|
+tE|ϵ1|
+e2γ
+2γ (1 − e−2γt)
+�
+.
+Hence, by Theorem A.1, the process Xn converges weakly to a continuous process
+X = (X(t), 0 ≤ t ≤ 1) which has independent Gaussian increments, zero mean
+vector and covariance matrix Γ(t).
+We now turn to the proof of the equation (30). From the proof of Theorem 1.1
+in Chapter 7 of Ethier and Kurtz (1986), we know that the limit process X can be
+represented by
+XT(t) =
+� t
+0
+Λ1/2(s) dBT(h(s)),
+0 ≤ t ≤ 1,
+
+24
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+where Λ(·) is a non-negative definite matrix-valued function, B = (B1, B2) is a
+2-dimensional standard Brownian motion, and
+h(t) = γ11(t) + γ22(t),
+0 ≤ t ≤ 1.
+In fact, the entries λij(·) of Λ(·) are the solutions of the following equations,
+�
+�
+�
+�
+�
+�
+�
+�
+�
+γ11(t) =
+� t
+0 λ11(s) dh(s),
+γ22(t) =
+� t
+0 λ22(s) dh(s),
+γ12(t) =
+� t
+0 λ12(s) dh(s),
+γ21(t) =
+� t
+0 λ21(s) dh(s).
+(44)
+Solving (44), we can get
+λ11(t) =
+e−2γ(1−t)
+e2γ(1−t) + e−2γ(1−t) = 1 − tanh(2γ(1 − t))
+2
+,
+λ22(t) =
+e2γ(1−t)
+e2γ(1−t) + e−2γ(1−t) = 1 + tanh(2γ(1 − t))
+2
+,
+λ12(t) =λ21(t) =
+E|ϵ1|
+e2γ(1−t) + e−2γ(1−t) =
+E|ϵ1|
+2 cosh(2γ(1 − t)).
+Hence we complete the proof of Lemma 5.3.
+□
+Theorem A.2 (Rootz´en, 1980) Let (B(t), 0 ≤ t ≤ 1) be a standard Brownian
+motion with respect to the filtration (Ft, 0 ≤ t ≤ 1). Suppose (φn(t), 0 ≤ t ≤ 1)n≥1
+is a sequence of random functions which is adapted to the filtration (Ft, 0 ≤ t ≤ 1).
+If
+sup
+0≤t≤1
+����
+� t
+0
+φn(s) ds
+���� →p 0,
+as n → ∞,
+and
+� 1
+0
+φ2
+n(t) dt →p τ,
+as n → ∞,
+for some random variable τ such that τ > 0 a.s., then
+� 1
+0 φn(t) dB(t)
+�� 1
+0 φ2n(t) dt
+→d N (0, 1),
+as n → ∞.
+Theorem A.3 (Graversen and Peskir, 2000) Let (V (t), t ≥ 0) be the Ornstein-
+Uhlenbeck process solving
+dV (t) = −βV (t)dt + dB(t)
+with V (0) = 0, where β > 0 and (B(t), t ≥ 0) is a standard Brownian motion, then
+there exist universal positive constants c0, c1 such that, for all stopping times τ of
+(V (t), t ≥ 0),
+c0
+√β E
+�
+log(1 + βτ) ≤ E
+�
+max
+0≤t≤τ |V (t)|
+�
+≤ c1
+√β E
+�
+log(1 + βτ).
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+25
+Proof of Lemma 5.4. Since
+sup
+0≤t≤1
+����
+� t
+0
+ϕγ(s) ds
+���� ≤
+� 1
+0
+|ϕγ(t)| dt,
+it is enough to show
+� 1
+0 |ϕγ(t)| dt →p 0 as γ → ∞. Notice that, from Lemma 5.3,
+L(t) ∼ N
+�
+0, e2γ(1 − e−2γt)
+2γ
+�
+,
+so
+E
+� 1
+0
+|ϕγ(t)| dt = 2γe−γ
+� 1
+0
+e−γ(1−t)E|L(t)| dt
+=
+�
+4γ/πe−γ
+� 1
+0
+�
+e2γt − 1 dt
+≤
+�
+4/(πγ)(1 − e−γ) → 0,
+as γ → ∞.
+By the Markov’s inequality, this establishes the equation (34).
+We next prove equation (35). Firstly, using integration by parts, we can get
+� 1
+0
+ϕ2
+γ(t) dt = 4γ2e−4γ
+� 1
+0
+e2γtL2(t) dt
+= 2γe−4γ
+� 1
+0
+L2(t) de2γt
+= 2γe−4γ
+�
+L2(1)e2γ −
+� 1
+0
+e2γt dL2(t)
+�
+.
+Furthermore, since
+�λ2
+12(t)h′(t) + �λ2
+22(t)h′(t) = e2γ(1−t),
+0 ≤ t ≤ 1,
+the Itˆo’s formula, together with equation (33), yields that
+dL2(t) = 2L(t) dL(t) + e2γ(1−t) dt.
+Therefore
+� 1
+0
+ϕ2
+γ(t) dt = 2γe−2γL2(1) − 2γe−2γ − 4γe−4γ
+� 1
+0
+e2γtL(t) dL(t).
+Noticing that
+L(1) ∼ N
+�
+0, e2γ − 1
+2γ
+�
+,
+we have
+2γe−2γL2(1) =d
+��
+1 − e−2γN (0, 1)
+�2 →p N 2(0, 1),
+as γ → ∞. In addition,
+E
+�
+4γe−4γ
+� 1
+0
+e2γtL(t) dL(t)
+�2
+= 16γ2e−6γ
+� 1
+0
+e2γtEL2(t) dt
+= 8γe−4γ
+� 1
+0
+(e2γt − 1) dt ≤ 4e−2γ → 0,
+
+26
+NANNAN MA, HAILIN SANG, AND GUANGYU YANG
+as γ → ∞. It follows from the Chebyshev’s inequality that
+4γe−4γ
+� 1
+0
+e2γtL(t) dL(t) →p 0,
+as γ → ∞.
+Hence we achieve the equation (35). The proof is complete.
+□
+Proof of Lemma 5.5. We first show that the equation (36) holds. Let
+dB∗(t) =
+�λ12(t)
+�
+h′(t)d �B1(t) + �λ22(t)
+�
+h′(t)d �B2(t)
+�
+�λ2
+12(t)h′(t) + �λ2
+22(t)h′(t)
+,
+then, by the L´evy characterization of Brownian motion, B∗ is a 1-dimensional
+standard Browinan motion. Since
+�λ2
+12(t)h′(t) + �λ2
+22(t)h′(t) = e2γ(1−t),
+0 ≤ t ≤ 1,
+the equation (33) implies that
+dL(t) = eγ(1−t)dB∗(t).
+Hence, by the Itˆo’s formula, we have
+� t
+0
+ψγ(s) ds =
+�
+−2γe−γ
+� t
+0
+eγsL(s)ds
+=
+√−2γe−γ
+γ
+�
+eγtL(t) −
+� t
+0
+eγs dL(s)
+�
+=
+√−2γ
+γ
+�� t
+0
+eγ(t−s) dB∗(t) − B∗(t)
+�
+.
+Therefore
+sup
+0≤t≤1
+����
+� t
+0
+ψγ(s) ds
+���� ≤
+� 2
+−γ
+�
+sup
+0≤t≤1
+����
+� t
+0
+eγ(t−s) dB∗(t)
+���� + sup
+0≤t≤1
+|B∗(t)|
+�
+.
+Obviously,
+� 2
+−γ
+�
+sup
+0≤t≤1
+|B∗(t)|
+�
+→p 0,
+as γ → −∞ and Theorem A.3 shows that
+E
+�� 2
+−γ sup
+0≤t≤1
+���
+� t
+0
+eγ(t−s) dB∗(t)
+���
+�
+≤ c1
+�
+2 log(1 − γ)
+−γ
+→ 0,
+as γ → −∞. By the Markov’s inequality again, we achieve the equation (36).
+Finally, we verify the equation (37). Notice that
+dL2(t) = 2L(t) dL(t) + e2γ(1−t) dt.
+It follows that � 1
+0
+ψ2
+γ(t) dt = −L2(1) + 1 + 2e−2γ
+� 1
+0
+e2γtL(t) dL(t).
+Since
+L(t) ∼ N
+�
+0, e2γ(1 − e−2γt)
+2γ
+�
+,
+we have
+L2(1) →p 0,
+as γ → −∞.
+
+LAD ESTIMATION FOR AR(1) PROCESSES
+27
+Moreover,
+E
+�
+2e−2γ
+� 1
+0
+e2γtL(t) dL(t)
+�2
+= 4e−4γ
+� 1
+0
+e4γte2γ(1−t)EL2(t) dt
+= 2
+γ
+� 1
+0
+(e2γt − 1) dt → 0,
+as γ → −∞. It concludes from the Chebyshev’s inequality that
+2e−2γ
+� 1
+0
+e2γtL(t) dL(t) →p 0.
+Hence we obtain the equation (37). The proof is complete.
+□
+Acknowledgment
+The authors would like to express their sincere gratitude to the anonymous
+referees and AE for helpful comments which surely lead to an improved presentation
+of this paper. The authors are very grateful to Huarui He, Hui Jiang, Feng Li,
+Yu Miao, Shaochen Wang and Qingshan Yang for the helpful discussions. Hailin
+Sang’s work was partially supported by the Simons Foundation grant 586789, USA.
+Guangyu Yang’s work was partially supported by the Foundation of Young Scholar
+of the Educational Department of Henan Province grant 2019GGJS012, China.
+Data Availability Statement: The data that support the findings of this study are
+available from the corresponding author upon reasonable request.
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+LAD ESTIMATION FOR AR(1) PROCESSES
+29
+(N. Ma) Zhengzhou Zhongyuan Sub-branch, Agricultural Bank of China, 450000,
+Henan, China.
+Email address: 1055165454@qq.com
+(H. Sang) Department of Mathematics, University of Mississippi, University, MS,
+38677, USA.
+Email address: sang@olemiss.edu
+(G. Yang) School of Mathematics and Statistics, Zhengzhou University, 450001, Henan,
+China.
+Email address: guangyu@zzu.edu.cn
+
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf,len=1276
+page_content='LEAST ABSOLUTE DEVIATION ESTIMATION FOR AR(1)  PROCESSES WITH ROOTS CLOSE TO UNITY  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We establish the asymptotic theory of least absolute deviation  estimators for AR(1) processes with autoregressive parameter satisfying n(ρn−  1) → γ for some fixed γ as n → ∞, which is parallel to the results of ordinary  least squares estimators developed by Andrews and Guggenberger (2008) in  the case γ = 0 or Chan and Wei (1987) and Phillips (1987) in the case γ ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Simulation experiments are conducted to confirm the theoretical results and  to demonstrate the robustness of the least absolute deviation estimation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Introduction  Consider the following AR(1) process  yi = ρyi−1 + ϵi,  1 ≤ i ≤ n,  where ρ is a deterministic parameter and {ϵi}i∈Z is a sequence of independent and  identically distributed (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=') random variables with mean zero and finite variance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  The asymptotic properties of the ordinary least squares (OLS) estimator of ρ have  been extensively studied in the literature;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' we refer to Anderson (1959), White  (1958), Dickey and Fuller (1979), Phillips (1987), Chan (2009), Miao and Shen  (2009), and references therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' To further handle the data that allows for large  shocks in dynamic structure of the process, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' modeling the asset-price bubbles,  it is usually to require the parameter ρ to depend on the sample size n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' On the  other hand, to understand the phenomena that the unit root test generally has a  low discriminatory power against the alternative of root close to but not equal to  unity, Bobkoski (1983) and Cavanagh (1985) introduced a local unit root model  with the parameter ρ depending on the sample size n and tending to unity as  n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Since then, many researchers systematically established the limit theory  for various near unit root processes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  See Chan and Wei (1987), Phillips (1987,  1988), Phillips and Magdalinos (2007), Aue and Horv´ath (2007), Andrews and  Guggenberger (2008), Buchmann and Chan (2013), Miao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2015), Jiang et  al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2022), Tanaka (2017), and references therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In particular, we refer to Stock  (1991) for the empirical research or Phillips (2021) for the recent theoretical progress  and empirical research on the processes with near unit roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Recently, Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020) studied the statistical  inference for the autoregressive parameter under the framework of the least absolute  deviation (LAD) estimation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' They proved that, if ρn → 1 and n|ρn − 1| → ∞ as  n → ∞, then the LAD estimators have normal and Cauchy asymptotic distributions  under the mildly-stationary case and the mildly-explosive case respectively, which  Key words and phrases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Asymptotic distribution;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' autoregressive processes;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' least absolute de-  viation estimation;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' local to unity;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' unit root test.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  1  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='02291v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='ST]  5 Jan 2023  2  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  are complementary to the results of the OLS estimators established by Giraitis and  Phillips (2006) and Phillips and Magdalinos (2007).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In fact, the LAD estimator  was first considered in the study of autoregressive processes in the case that the  regressive parameters are constants and the innovations have infinite variance due  to the robust property of LAD estimation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For example, see the papers, Pollard  (1991), Phillips (1991), Davis et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (1992), and Li and Li (2009).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Specially, Herce  (1996) studied the asymptotic property of the LAD estimator in a unit root process  with finite variance innovations and correspondingly developed the unit root test  in this case which complement similar ones obtained by Knight (1989).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Motivated by the above work, the goal of the present article is to establish  the asymptotic theory of LAD estimators for AR(1) processes when the regressive  parameter satisfies n(ρn −1) → 0 or n(ρn −1) → γ for some fixed γ ̸= 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  To the best of our knowledge, this part of research is still missing although we  already have a rich literature in LAD estimations and unit root test for AR(1)  processes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' It is shown that, if n(ρn − 1) → 0 as n → ∞, the limiting distributions  are dominated by the initial conditions both in the near-stationary case and the  near-explosive case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  This phenomena have been studied by M¨uller and Elliott  (2003), Phillips and Magdalinos (2009), and references therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Our results in the  near-stationary case correspond exactly to the theory on the OLS estimators for the  same model developed by Andrews and Guggenberger (2008).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' With the condition  n(ρn − 1) → γ for some fixed γ ̸= 0 as n → ∞, we study the asymptotic theory  of the LAD estimator under the assumption y0 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  The work in this case is  complementary to the theory of the OLS estimation developed by Chan and Wei  (1987) and Phillips (1987).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  This paper is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' After introducing the model, we state the  main results in Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Section 3 reports some simulation studies to illustrate  the finite sample performance and to confirm the asymptotic results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Section 4  consists of concluding remarks and Section 5 provides the proofs of main results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  All the other technical proofs are given in Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Throughout this paper, the symbols ‘→d’, ‘→p’ and ‘=d’ denote the weak conver-  gence, convergence in probability and equality in distribution, respectively;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' op(1)  means tending to zero in probability;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' C denotes the standard Cauchy random vari-  able and N (µ, σ2) denotes the normal random variable with mean µ and variance  σ2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' [x] represents the integral part of x;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' sign(·) is the signum function;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' IA is the  indicator function of set A and det(M) is the determinant of matrix M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Main results  Suppose that the data {yi} are generated by the following autoregressive model  with order one  yi = ρnyi−1 + ϵi,  1 ≤ i ≤ n,  (1)  where the parameter ρn satisfies ρn → 1 as n → ∞, and the noises {ϵi}i∈Z satisfy  the following assumptions:  (i).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' {ϵi}i∈Z are i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' random variables with mean zero and finite variance σ2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (ii).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' ϵ1 has zero median and a differentiable density function f(x) in R with  f(0) > 0 and supx∈R |f ′(x)| < ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  3  Note that, formally the data {yi} is a triangular array but here n is omitted for  notational simplicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' With the above assumptions on the noises, one can also study  the estimation of the parameter ρn with ρn → −1 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For the purpose of  simplicity, we only state the results for the positive ρn case in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  The LAD estimator of ρn is defined as a solution of the following extremum  problem  ˆρLAD = arg min  ρ∈R  �  1  n  n  �  i=1  |yi − ρyi−1|  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (2)  Notice that, the LAD estimators usually do not have closed forms and are not  unique if the object function has a flat segment;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' see, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Herce (1996).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Moreover,  the LAD estimators are robust, especially they are not significantly affected by the  presence of outliers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' This is confirmed by the simulation study in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The case n(ρn − 1) → 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We first consider the case that the  parameter ρn satisfies n(ρn − 1) → 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  That is, the autoregressive  parameter ρn is very nearly unity in the sense that ρn is away from unity by  o(n−1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The following two theorems are the main results in this case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' One is for  the near-stationary case 0 < ρn < 1 and the other is for the near-explosive case  ρn > 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 (The near-stationary case).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For model (1) with 0 < ρn < 1 and  n(ρn − 1) → 0 as n → ∞, assume that y0 depends on the full past of the noise, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  y0 = �∞  j=0 ρj  nϵ−j, then, as n → ∞, we have  �  n  1 − ρ2n  (ˆρLAD − ρn) →d  C  2σf(0)  (3)  and  �  �  �  �  n  �  i=1  y2  i−1 (ˆρLAD − ρn) →d N  �  0,  1  4f 2(0)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (4)  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 (The near-explosive case).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For model (1) with ρn > 1 and n(ρn −  1) → 0 as n → ∞, assume that y0 is an infinitely distant initialization, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' y0 =  �κn  j=0 ρj  nϵ−j, with κn/n → ∞ and κn(ρn − 1) → 0 as n → ∞, then, as n → ∞, we  have  √nκn (ˆρLAD − ρn) →d  C  2σf(0)  (5)  and  �  �  �  �  n  �  i=1  y2  i−1 (ˆρLAD − ρn) →d N  �  0,  1  4f 2(0)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (6)  We give some comments on Theorems 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Since the AR(1) model (1) is causal when 0 < ρn < 1, the initial  value y0 can be written as a linear combination over the past information in the  linear process form y0 = �∞  j=0 ρj  nϵ−j.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In the same case, ρn ∈ (−1, 1), n(ρn −  1) → 0 and y0 depends on the full past of the noise, Andrews and Guggenberger  (2008) obtained the limit theorems for the OLS estimators which are similar to  4  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 except for the appearance of f(0) here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Furthermore, because the  limiting distributions of the t-type estimator include f(0) in LAD estimations, in  practice we use the following density estimator (Silverman, 1986) for statistical  inference  ˆfn(0) :=  1  nbn  n  �  i=1  K  �yi − ˆρLADyi−1  bn  �  ,  where bn is the bandwidth and K(·) is a kernel function, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  the Gaussian or  logistic kernel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' As we mentioned previously, Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (2020) studied the LAD estimations for ρn satisfying n|ρn − 1| → ∞ where the  initial value y0 = op(|ρn − 1|−1/2) independent of {ϵi, i ≥ 1}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' To be explicit, they  obtained that  �  �  �  �  n  1−ρ2n (ˆρLAD − ρn) →d N  �  0,  1  4f 2(0)  �  ��n  i=1 y2  i−1 (ˆρLAD − ρn) →d N  �  0,  1  4f 2(0)  �  (7)  and  ρn  n  ρ2n − 1 (ˆρLAD − ρn) →d  C  2σf(0),  (8)  for the mildly-stationary case and the mildly-explosive case, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Their  results match the classic results in Phillips and Magdalinos (2007) except for the  appearance of f(0), just like the usual LAD estimations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  It is worth pointing out that, here for the very nearly unit root processes, Theorem  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 show that, in both near-stationary and near-explosive cases,  the initial value y0 dominates the asymptotic distributions of the LAD estimator  and the t-type estimator which are Cauchy and normal respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Moreover,  since ρn → 1 at a much faster rate than 1/n, for the near-stationary case, by  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, the assumption y0 = op(|ρn −1|−1/2) can not hold and the convergence  rate  �  n/(1 − ρ2n) has a larger order than n which enlarges the convergence rate  spectrum, while, for the near-explosive case, the convergence rate √nκn also has a  large order than n which is different from that in equation (8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The case n(ρn − 1) → γ as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Now we consider the local unit root  case that the parameter ρn satisfies n(ρn − 1) → γ for some fixed γ ̸= 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We remark that, unlike the case, ρn ̸= 1 and n(ρn − 1) → 0 as n → ∞, where  the initial condition entirely dominates the asymptotic distribution of the sample  variance �n  i=1 y2  i−1, in this case, the initial value depending on the past of the noise  does not affect the analysis methods essentially so we can assume that y0 = 0 for  simplicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  To state the main results, we first introduce some notations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For 1 ≤ i ≤ n, let  Kn,i :=  1  √nρi−1−n  n  sign(ϵi)  and  Ln,i :=  1  √nρn−i  n  ϵi,  and define  Kn(t) :=  [nt]  �  i=1  Kn,i  and  Ln(t) :=  [nt]  �  i=1  Ln,i,  (9)  LAD ESTIMATION FOR AR(1) PROCESSES  5  for 0 ≤ t ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  If we further assume that σ2 = 1 and E|ϵ1|2+δ < ∞ for some  δ > 0, by Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3, the process {(Kn(t), Ln(t)), 0 ≤ t ≤ 1} converges weakly to  a continuous process  X(t) = (K(t), L(t)),  0 ≤ t ≤ 1  (10)  with independent Gaussian increments, mean vector zero and covariance matrix  Γ(t) = (γij(t)) :=  �  e−2γ  2γ (e2γt − 1)  tE|ϵ1|  tE|ϵ1|  e2γ  2γ (1 − e−2γt)  �  ,  0 ≤ t ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (11)  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For model (1), assume that y0 = 0, σ2 = 1, n(ρn − 1) → γ for  some fixed γ ̸= 0 as n → ∞, and E|ϵ1|2+δ < ∞ for some δ > 0, then, as n → ∞,  we have  n(ˆρLAD − ρn) →d  1  2f(0) ·  � 1  0 L(t) dK(t)  � 1  0 e−2γ(1−t)L2(t) dt  (12)  and  �  �  �  �  n  �  i=1  y2  i−1 (ˆρLAD − ρn) →d  1  2f(0) ·  � 1  0 L(t) dK(t)  �� 1  0 e−2γ(1−t)L2(t) dt  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (13)  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020) worked on the case that  ρn → 1 and n|ρn−1| → ∞ as n → ∞, where the convergence rate for the asymptotic  distributions of the LAD estimators has an order in the range (n1/2, n) for the  mildly-stationary case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Together with the results in Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2,  we enlarge the convergence rate spectrum in the asymptotic distributions of the  LAD estimators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The similar relationship between the rate of ρn and the rate in  the asymptotic distributions was observed for OLS estimators in the literature, see,  e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Chan and Wei (1987), Phillips (1987), Phillips and Magdalinos (2007), and  Andrews and Guggenberger (2008).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let  D(γ) :=  1  2f(0) ·  � 1  0 L(t) dK(t)  � 1  0 e−2γ(1−t)L2(t) dt  (14)  and  L (γ) :=  1  2f(0) ·  � 1  0 L(t) dK(t)  �� 1  0 e−2γ(1−t)L2(t) dt  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (15)  Notice that D(γ) and L (γ) are continuous families of distributions indexed by the  parameter γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Thus, for the case, ρn = 1 + γ/n, by Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3, when γ = 0, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  ρn ≡ 1, we have  D(0) =  1  2f(0) ·  � 1  0 W2(t) dW1(t)  � 1  0 W 2  2 (t) dt  and  L (0) =  1  2f(0) ·  � 1  0 W2(t) dW1(t)  �� 1  0 W 2  2 (t) dt  ,  here W = (W1, W2) is a bivariate Brownian motion with covariance matrix  Ξ =  �  1  E|ϵ1|  E|ϵ1|  1  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  6  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  These exactly correspond to the main results in Herce (1996), where the author  discussed the structure of D(0), a combination of a “unit root” distribution and a  scale mixture of normal distributions, and used it to construct the LAD-based unit  root tests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In addition, since σ2 = 1, we have E|ϵ1| ≤ 1, hence the matrix Ξ is non-  negative definite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' However, here D(γ) and L (γ) are too complicate to be analyzed  effectively so we do some simulations to give an overall view on the distributions of  D(γ) and L (γ) in Section 3 which illustrate how they depend on the parameter γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Finally, we also remark that, from Theorem 1 in Herce (1996), the local unit root  case has the optimal rate of convergence for the alternative hypothesis, that is, it  has the same rate as in the unit root case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Followed the above remark, there is a natural question, what can we say about  the distributions of L (γ) as |γ| → ∞?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In fact, like the case for the OLS estimators  in Chan and Wei (1987) and Phillips (1987), we have the following result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For model (1), assume that y0 = 0, σ2 = 1, n(ρn − 1) → γ for  some fixed γ ̸= 0 as n → ∞, and E|ϵ1|2+δ < ∞ for some δ > 0, then we have  2f(0) · L (γ) →d N (0, 1),  as |γ| → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (16)  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Recall from Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2, Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (2020) proved that  2f(0) ·  �  �  �  �  n  �  i=1  y2  i−1 (ˆρLAD − ρn) →d N (0, 1) ,  (17)  for the mildly-stationary case, 0 < ρn < 1 and n(1−ρn) → ∞ as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Theorem  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4 together with Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 yields that, if let n(ρn − 1) → γ first, and then let  |γ| → ∞, we can also get the asymptotic normal distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Moreover, it is worth  noting that, although Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4 holds for γ → ∞ and γ → −∞, the underlying  reasoning is quite different between these two cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In fact, for the large negative  γ’s, ρn can be thought of much less than one so the model (1) can be regarded  as stationary and then the asymptotic normality holds;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' for the positive γ, ρn is  larger than one and the model (1) is explosive, however Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4 shows that the  asymptotic normality is still valid which is different from the mildly-explosive case  discussed in Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' the equation (8) in  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' simulations  In this section, we work on Monte Carlo simulation to examine the finite sam-  ple performance of the estimators in our main results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  For convenience, in all  experiments, we always suppose that the data are generated by the AR(1) model,  yi = ρnyi−1 + ϵi with ρn = 1 + γn−β for some γ ∈ R and β ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Furthermore,  we also assume that the innovations are i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' and have N (0, 1) or U(−1, 1) dis-  tributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Here U(−1, 1) denotes the uniform random variable on the interval  (−1, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' To estimate the parameter f(0), we apply the following density estimator  (Silverman, 1986)  ˆfn(0) =  1  nbn  n  �  i=1  K  �yi − ˆρLADyi−1  bn  �  ,  LAD ESTIMATION FOR AR(1) PROCESSES  7  where K(·) is the Gaussian kernel and the optimal bandwidth bn associated with  the Matlab function ksdensity(·, 0) is automatically selected from the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Density curves of estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We first consider the simulations of Theorem  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For the near-stationary case, y0 = �∞  j=0 ρj  nϵ−j, the true  parameters are taken to be (γ, β) = (−10, 2) and we denote the normalized esti-  mator by ˆρs = 2σ ˆfn(0)  �  n/(1 − ρ2n)(ˆρLAD − ρn).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For the near-explosive case, take  y0 = �κn  j=0 ρj  nϵ−j, (γ, β) = (10, 2), κn = [n1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3], and denote the normalized estimator  by ˆρe = 2σ ˆfn(0)√nκn(ˆρLAD − ρn).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For both cases, denote the t-type estimators by  Tn := 2 ˆfn(0)  ��n  i=1 y2  i−1 (ˆρLAD − ρn).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We simulate 3000 replications with sample  size n = 1000 for each case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Figure 1 shows that the density curves of ˆρs and ˆρe  are close to that of the standard Cauchy random variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Figure 2 confirms the  asymptotic normality of Tn in the near-stationary and near-explosive cases by using  the Q-Q graphs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Next we simulate the limiting distributions, D(γ) and L (γ), defined as in Re-  mark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let β = 1 and suppose that the innovations are standard normal random  variables so f(0) = 1/  √  2π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For D(γ), simulate 1000 replications with sample size  n = 200 for each case;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Figure 3 illustrates the shape of the asymptotic density  curves of 2f(0)D(γ) for different γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  For L (γ), simulate 1000 replications with  sample size n = 2000 (γ < 0) and n = 1000 (γ > 0) for each case;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Figure 4 confirms  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' the asymptotic normality of 2f(0)L (γ) as |γ| → ∞, which also  demonstrates the difference of the convergence rate between γ → ∞ and γ → −∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  −5  −4  −3  −2  −1  0  1  2  3  4  5  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='6  N(0,1)  U(−1,1)  Cauchy  (a) The near-stationary case  −5  −4  −3  −2  −1  0  1  2  3  4  5  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='6  N(0,1)  U(−1,1)  Cauchy  (b) The near-explosive case  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Density curves of ˆρs and ˆρe with N (0, 1) and U(−1, 1) in-  novations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  8  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  4  2  0  2  4  4  3  2  1  0  1  2  3  (a) The near-stationary case  4  2  0  2  4  4  3  2  1  0  1  2  3  (b) The near-explosive case  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Q-Q graphs of statistics Tn with N (0, 1) innovation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  −30  −20  −10  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5  gamma=−1  gamma=−5  gamma=−15  density of standard normal  (a) The near-stationary case  −30  −25  −20  −15  −10  −5  0  5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5  gamma=1  gamma=2  gamma=3  density of standard normal  (b) The near-explosive case  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Asymptotic density curves of 2f(0)D(γ) with N (0, 1) inno-  vation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  9  −10  −8  −6  −4  −2  0  2  4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5  gamma=−2  gamma=−20  gamma=−300  density of standard normal  (a) The near-stationary case  −15  −10  −5  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5  gamma=1  gamma=5  gamma=30  density of standard normal  (b) The near-explosive case  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Asymptotic density curves of 2f(0)L (γ) with N (0, 1) inno-  vation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Accuracy of Estimators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Andrews and Guggenberger (2008) achieved the as-  ymptotic theory of OLS estimators for model (1) with n(ρn − 1) → 0 and 0 <  ρn < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Here we will compare the accuracy between the estimators ˆρLAD and  ˆρOLS, where ˆρOLS denotes the OLS estimator of ρn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For the near-stationary case,  let y0 = �∞  j=0 ρj  nϵ−j, β = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 and γ = −5, −50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Here we add 10 for each  randomly selected 5% sample points to construct outliers when generating data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In  these experiments, we simulate 1000 replications each with sample size n = 200 or  500 to compare the empirical means (EM), absolute errors (AE) and mean squared  errors (MSE) of ˆρLAD and ˆρOLS in two cases, with and without outliers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In the  case without outliers, Table 1 shows that EM is very close to the true value ρn  and AE and MSE are very small, which verifies the accuracy of LAD estimator for  very nearly unit root model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The errors (AE and MSE) decrease as the sample  size n increases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' If there are outliers in the data, Table 2 shows that the errors  (AE and MSE) of OLS estimator are much larger than those of LAD estimator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Furthermore, the OLS estimator occasionally produces estimates greater than one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence it is concluded that ˆρLAD is more robust than ˆρOLS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  For the near-explosive case, we take κn = [n1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3] in y0 = �κn  j=0 ρj  nϵ−j, and let  β = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='8, γ = 5, 50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The selection of the parameter values here guarantees that  n(ρn − 1) → 0, κn(1 − ρn) → 0 and κn/n → ∞, as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Since the y values from  different cases have quite different scales, here we add 10 times of the absolute value  of the maximum for each randomly selected 5% sample points to construct outliers  when generating data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In these experiments, we simulate 1000 replications each  with sample size n = 200 or 500 and study the empirical means (EM), absolute  errors (AE) and mean squared errors (MSE) of ˆρLAD and ˆρOLS in two cases, with  and without outliers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Table 3 shows that, if there are no outliers in the data, EM  is very close to the true value ρn and AE and MSE are very small, which verifies  10  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  the accuracy of the LAD estimator and OLS estimator, while, if there are outliers  in the data, it is clear from Table 4 that ˆρLAD is more robust than ˆρOLS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' AE/EM and MSE of ˆρLAD(ˆρOLS) for near-stationary AR(1)  processes with N (0, 1), U(−1, 1) noises: no outliers case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  ϵi  N(0, 1)  U(−1, 1)  β  γ  n  ρn  AE/EM  MSE  AE/EM  MSE  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  50  200  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='8528  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='0097/0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='8431  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='0127  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
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+page_content='9476)  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Concluding remarks  In this article we develop the limit theory of the LAD estimator for the AR(1)  process with a root close to unity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The parameter ρn satisfies n(ρn − 1) → 0 or  n(ρn −1) → γ for some fixed number γ ̸= 0, as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' It is shown that, in the first  case, for both near-stationary and near-explosive processes, the LAD estimator and  the t-type statistic have Cauchy and normal asymptotic distribution, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  The simulation study in this case confirms the theoretical results and it illustrates  that the theory should be useful in statistical inference and the LAD estimator is  12  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  robust if there are outliers in the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In the case that n(ρn − 1) → γ for some  fixed number γ ̸= 0, as n → ∞, we also develop asymptotic theory for the LAD  estimator and the t-type statistic under the assumption that y0 = 0 which gives us  the connection with the existing results in literature, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Chan and Wei (1987),  Phillips (1987), and Herce (1996).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  In summary, we establish the asymptotic theory of the LAD estimators for the  nearly unit root processes which correspond to the results of the OLS estimators  developed by Chan and Wei (1987), Phillips (1987, 1988, 2021), Phillips and Mag-  dalinos (2007), Andrews and Guggenberger (2008), Chan (2009) and so on.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The  results in this article are also the completion of the LAD estimators studied in  Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' These authors worked on the case  that ρn → 1 and n|ρn − 1| → ∞ as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The normalizer of the asymptotic  distributions for the LAD estimators there has a rate in the range (n1/2, n) for  the near-stationary case.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We enlarge the rate spectrum of the normalizer in the  asymptotic distributions of the LAD estimators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Proof of main results  We first give some comments on the proofs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' It is known that the methods of  the LAD estimation are classic which were developed by Pollard (1991), Davis et  al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (1992), Knight (1989, 1998) and Ling (2005).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The limiting behaviors of the  quadratic functionals, �n  i=1 y2  i−1 and �n  i=1 yi−1sign(ϵi), play the crucial role in the  analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Concretely, for the very nearly case, n(ρn − 1) → 0, we mainly follow  the strategies of Zhou and Lin (2014) and Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020), while, under our  framework, the initial values y0 dominate the asymptotic behavior of �n  i=1 y2  i−1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  see Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' More work is required for the local unit root case,  n(ρn − 1) → γ for some γ ̸= 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  To treat the asymptotic joint distributions of  � 1  n  �n  i=1 yi−1sign(ϵi), 1  n2  �n  i=1 y2  i−1  �  , we need to develop a functional central limit  theorem for the process {(Kn(t), Ln(t)), 0 ≤ t ≤ 1} defined as in (9), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Lemma  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3, by the vector-value martingale invariance principle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We remark that, although  Phillips and Durlauf (1986) (Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1) established the asymptotic theory for  sample moments of vector-value integrated processes, their results can not be used  here because the regression parameter ρn depends on the sample size n which causes  the covariance matrix defined as in (11) to be time-dependent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Finally, by using the  tools from stochastic calculus, we achieve the estimates, Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4 and Lemma  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5, which is the key of the proof in Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Throughout the proof, we use the following identity of Knight (1998),  for x ̸= 0,  |x − y| − |x| = −ysign(x) + 2  � y  0  �  I{x≤s} − I{x≤0}  �  ds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (18)  From the model (1), we also observe that  yi = ρi  ny0 +  i  �  j=1  ρi−j  n  ϵj,  1 ≤ i ≤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (19)  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The case n(ρn−1) → 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In this subsection, we will prove Theorem  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let us start by presenting two lemmas proved in Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Under the assumptions of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, we have  LAD ESTIMATION FOR AR(1) PROCESSES  13  (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  �  1 − ρ2ny0 →d σX;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  1  √n  �n  i=1 ρi−1  n  sign(ϵi) →d Y ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  �  (1 − ρ2n)/n max1≤i≤n |yi−1| →p 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  here X and Y are independent standard normal random variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Under the assumptions of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2, we have  (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  1  √κn y0 →d σU;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  1  √n  �n  i=1 ρi−1  n  sign(ϵi) →d V ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  1  √nκn max1≤i≤n |yi−1| →p 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  here U and V are independent standard normal random variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Denote ˆun =  �  n/(1 − ρ2n)(ˆρLAD − ρn).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Then ˆun is the  minimizer of the following convex objective function,  Zn(u) =  n  �  i=1  �  |ϵi −  �  (1 − ρ2n)/nyi−1u| − |ϵi|  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Based on the ideas of Davis et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (1992) and Ling (2005), if we can prove that, for  each u, Zn(u) converges weakly to a random variable which has a unique minimizer  umin, then ˆun must converge weakly to umin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  By (18), we rewrite Zn(u) as follows  Zn(u) = −uAn + 2  n  �  i=1  ξi(u),  (20)  here  An =  �  (1 − ρ2n)/n  n  �  i=1  yi−1sign(ϵi)  and  ξi(u) =  � √  (1−ρ2  n)/nyi−1u  0  �  I{ϵi≤s} − I{ϵi≤0}  �  ds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Next we analyze the asymptotic properties of An and ξi(u), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' By (19),  we can decompose An as follows  An =  �  (1 − ρ2n)/n  n  �  i=1  �  ρi−1  n  y0 +  i−1  �  j=1  ρi−1−j  n  ϵj  �  sign(ϵi)  =  �  (1 − ρ2n)y0 ·  1  √n  n  �  i=1  ρi−1  n  sign(ϵi) + Rn,1,  (21)  where the remainder  Rn,1 =  �  (1 − ρ2n)/n  n  �  i=1  i−1  �  j=1  ρi−1−j  n  ϵj sign(ϵi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  The parts (1) and (2) of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, together with the continuous mapping theorem,  yield that the first term in the equation (21) converges weakly to the random  variable σXY , where X and Y are independent standard normal random variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  14  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  Now, we show that the remainder converges to zero in probability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Obviously, by  simple calculations, E(Rn,1) = 0 and  E(R2  n,1) = 1 − ρ2  n  n  E  ��  n  �  i=1  i−1  �  j=1  ρi−1−j  n  ϵj sign(ϵi)  �2�  = 1 − ρ2  n  n  n  �  i=1  E  �� i−1  �  j=1  ρi−1−j  n  ϵj  �2�  = n − 1  n  �  1 −  ρ2  n − ρ2n  n  (n − 1)(1 − ρ2n)  �  σ2 → 0  as n → ∞, where the last step is due to Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Consequently, An  converges weakly to the random variable σXY .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We now analyze the second term �n  i=1 ξi(u) in the equation (20) by the mar-  tingale method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Denote the filtration by Fn,i = σ(y0, ϵ1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' , ϵi) for 1 ≤ i ≤ n and  n ≥ 1, then we can write  n  �  i=1  ξi(u) =  n  �  i=1  E(ξi(u)|Fn,i−1) + Rn,2,  where the remainder  Rn,2 =  n  �  i=1  (ξi(u) − E(ξi(u)|Fn,i−1)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  is a martingale with respect to the filtration, {Fn,i, 1 ≤ i ≤ n}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  By the Taylor’s formula,  n  �  i=1  E(ξi(u)|Fn,i−1) =  n  �  i=1  � √  (1−ρ2n)/nyi−1u  0  E  �  I{ϵi≤s} − I{ϵi≤0}  �  ds  =  n  �  i=1  � √  (1−ρ2n)/nyi−1u  0  (F(s) − F(0)) ds  =  n  �  i=1  � √  (1−ρ2n)/nyi−1u  0  �  f(0)s + 1  2f ′(s∗)s2�  ds  = u2f(0)  2  1 − ρ2  n  n  n  �  i=1  y2  i−1 + Rn,3,  (22)  where F(·) is the distribution function of ϵ1, s∗ ∈ (0, s) and the remainder  Rn,3 = 1  2  n  �  i=1  � √  (1−ρ2n)/nyi−1u  0  f ′(s∗)s2ds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We first consider the sample variance, �n  i=1 y2  i−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' From equation (19),  n  �  i=1  y2  i−1 =  n  �  i=1  ρ2(i−1)  n  y2  0 +  n  �  i=1  ρi−1  n  i−1  �  j=1  ρi−j−1  n  ϵjy0 +  n  �  i=1  � i−1  �  j=1  ρi−j−1  n  ϵj  �2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (23)  Simple calculations yield that  E  �  n  �  i=1  � i−1  �  j=1  ρi−j−1  n  ϵj  �2�  =  n  �  i=1  i−1  �  j=1  ρ2(i−1−j)  n  σ2 = (n − 1)σ2  1 − ρ2n  �  1 −  ρ2  n − ρ2n  n  (n − 1)(1 − ρ2n)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  15  Note that, by the Cauchy-Schwarz’s inequality,  ���  n  �  i=1  ρi−1  n  i−1  �  j=1  ρi−j−1  n  ϵj  ���  2  ≤  n  �  i=1  ρ2(i−1)  n  n  �  i=1  � i−1  �  j=1  ρi−j−1  n  ϵj  �2  ,  so, applying Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 for kn = n and part (1) of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, for the second  term in (23), we can obtain  1 − ρ2  n  n  n  �  i=1  ρi−1  n  i−1  �  j=1  ρi−j−1  n  ϵjy0 →p 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  It also follows, for the third term in (23),  1 − ρ2  n  n  n  �  i=1  � i−1  �  j=1  ρi−j−1  n  ϵj  �2  →p 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Moreover, Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and part (1) of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, combined with the contin-  uous mapping theorem, imply that  1 − ρ2  n  n  n  �  i=1  ρ2(i−1)  n  y2  0 →d σ2X2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Therefore, we have shown that  1 − ρ2  n  n  n  �  i=1  y2  i−1 →d σ2X2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (24)  It remains to deal with the remainders, Rn,2 and Rn,3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Notice that  |Rn,3| ≤ |u|3 supx∈R |f ′(x)|  3  �1 − ρ2  n  n  �3/2  n  �  i=1  |yi−1|3  ≤ |u|3 supx∈R |f ′(x)|  3  �1 − ρ2  n  n  �3/2  max  1≤i≤n |yi−1|  n  �  i=1  y2  i−1,  by equation (24) and part (3) of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, Rn,3 converges to zero in probability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Since Rn,2 is a martingale, with the methods of Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020) or Zhou and  Lin (2014) and the help of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, we can prove that Rn,2 converges to zero in  probability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Summarizing above discussions, we get that  Zn(u) = −uAn + 2  n  �  i=1  ξi(u)  = −u  �  (1 − ρ2n)y0 ·  1  √n  n  �  i=1  ρi−1  n  sign(ϵi) + u2f(0)1 − ρ2  n  n  n  �  i=1  ρ2(i−1)  n  y2  0 + op(1)  →d −uσXY + u2σ2f(0)X2 =: Z(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Because Z(u) has a unique minimum at  umin = Y/(2σf(0)X),  16  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 of Davis et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (1992), we derive that  ˆun =  �  n/(1 − ρ2n)(ˆρLAD − ρn) →d  1  2σf(0)C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Combining this with equation (24) and using the continuous mapping theorem, we  complete the proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The proof is similar to that of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In this case,  ˆun = √nκn(ˆρLAD − ρn), Zn(u) = �n  i=1  �  |ϵi − (nκn)−1/2yi−1u| − |ϵi|  �  , and in (20),  An =  1  √nκn  n  �  i=1  yi−1sign(ϵi)  and  ξi(u) =  � yi−1u/√nκn  0  �  I{ϵi≤s} − I{ϵi≤0}  �  ds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 is applied to prove the corresponding terms as in the proof of Theorem  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Here we only partially demonstrate the role of the assumptions, κn/n → ∞  and κn(ρn − 1) → 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let us consider the normalized sample variance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  For the third term of (23), we want to show that  1  nκn  n  �  i=1  � i−1  �  j=1  ρi−j−1  n  ϵj  �2  →p 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  By a simple calculation, we get  E  �  n  �  i=1  � i−1  �  j=1  ρi−j−1  n  ϵj  �2�  =  n  �  i=1  i−1  �  j=1  ρ2(i−1−j)  n  σ2 = (n − 1)σ2  1 − ρ2n  �  1 −  ρ2  n − ρ2n  n  (n − 1)(1 − ρ2n)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Then, Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 yields that  1  nκn  (n − 1)σ2  1 − ρ2n  �  1 −  ρ2  n − ρ2n  n  (n − 1)(1 − ρ2n)  �  = O  � n  κn  �  ,  which tends to zero if κn/n → ∞ as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The proof is complete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The case n(ρn−1) → γ as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In this subsection, we will prove Theorem  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Firstly, we prove Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 following the line as in the proofs of the case  n(ρn − 1) → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In this case, ˆun = n(ˆρLAD − ρn) and it is the minimizer of the  following convex function,  Zn(u) =  n  �  i=1  �  |ϵi − n−1yi−1u| − |ϵi|  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (25)  Again by the Knight’s identity (18), we can rewrite the quantity Zn(u) in (25) as  identity (20) with  An = 1  n  n  �  i=1  yi−1sign(ϵi)  (26)  and  ξi(u) =  � n−1yi−1u  0  �  I{ϵi≤s} − I{ϵi≤0}  �  ds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (27)  LAD ESTIMATION FOR AR(1) PROCESSES  17  Again we use the filtration Fn,i = σ(y0, ϵ1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' , ϵi) for 1 ≤ i ≤ n and n ≥ 1, and  write  n  �  i=1  ξi(u) =  n  �  i=1  E(ξi(u)|Fn,i−1) + Rn,1,  where  Rn,1 =  n  �  i=1  (ξi(u) − E(ξi(u)|Fn,i−1))  (28)  is a martingale with respect to the filtration, {Fn,i, 1 ≤ i ≤ n}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  By the same  argument as in (22),  n  �  i=1  E(ξi(u)|Fn,i−1) = u2f(0)  2  1  n2  n  �  i=1  y2  i−1 + Rn,2,  where  Rn,2 = 1  2  n  �  i=1  � n−1yi−1u  0  f ′(s∗)s2ds  (29)  and s∗ is between 0 and s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' As in the proofs of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2, to  obtain the asymptotic distribution of Zn(u), the key point is to analyze the joint  distribution of  � 1  n  �n  i=1 yi−1sign(ϵi), 1  n2  �n  i=1 y2  i−1  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Under the assumptions of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3, the process (Kn(t), Ln(t), 0 ≤  t ≤ 1) defined as in (9) converges weakly to the continuous process (X(t), 0 ≤ t ≤ 1)  defined as in (10) with independent Gaussian increments, mean vector zero and  covariance matrix Γ(t) defined as in (11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Moreover, we also have  XT(t) =  � t  0  Λ1/2(s) dBT(h(s)),  0 ≤ t ≤ 1,  (30)  where Λ(·) is a non-negative definite matrix-valued function given by  Λ(t) = (λij(t)) := 1  2  � 1 − tanh(2γ(1 − t))  E| ϵ1|sech(2γ(1 − t))  E| ϵ1|sech(2γ(1 − t))  1 + tanh(2γ(1 − t))  �  ,  0 ≤ t ≤ 1,  B = (B1, B2) is a 2-dimensional standard Brownian motion and  h(t) = 1  γ  �  sinh(2γ) − sinh(2γ(1 − t))  �  ,  0 ≤ t ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Under the assumptions of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3, as n → ∞,  �  1  n  n  �  i=1  yi−1sign(ϵi), 1  n2  n  �  i=1  y2  i−1  �  →d  �� 1  0  L(t) dK(t),  � 1  0  e−2γ(1−t)L2(t) dt  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Observe that  1  n  n  �  i=1  yi−1sign(ϵi) =  n  �  i=1  �  � 1  √n  i−1  �  j=1  ρn−j  n  ϵj  �  � 1  √nρi−1−n  n  sign(ϵi)  =  � 1  0  Ln(t) dKn(t)  18  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  and  1  n2  n  �  i=1  y2  i−1 =  n  �  i=1  1  n  �  � 1  √n  i  �  j=1  ρi−j  n  ϵj  �  �  2  =  � 1  0  e−2γ(1−t)L2  n(t) dt + Rn,3,  where the remainder  Rn,3 = 1  n  n  �  i=1  ρ2(i−n)  n  L2  n  � i  n  �  −  � 1  0  e−2γ(1−t)L2  n(t) dt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  According to the same argument in the proof of Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 in Chan and Wei (1987),  we can show that Rn,3 →p 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Hence Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 in Hansen (1992) and  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 immediately yield the desired result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Recall the analysis in the beginning of this subsection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Notice that Rn,2 in (29) satisfies  2|Rn,2| ≤ |u|3 supx∈R |f ′(x)|  3  1  n3  n  �  i=1  |yi−1|3  ≤ |u|3 supx∈R |f ′(x)|  3  1  n max  1≤i≤n |yi−1| · 1  n2  n  �  i=1  y2  i−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (31)  By Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 and Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2, Rn,2 converges to zero in probability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In  addition, following the same line of Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (2020) or Zhou and Lin (2014), we  can also show that Rn,1 in (28) converges to zero in probability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Combining with  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, we have  Zn(u) = −uAn + 2  n  �  i=1  ξi(u)  →d −u  � 1  0  L(t) dK(t) + u2f(0)  � 1  0  e−2γ(1−t)L2(t) dt =: Z(u).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Because Z(u) has a unique minimum at  umin =  1  2f(0) ·  � 1  0 L(t) dK(t)  � 1  0 e−2γ(1−t)L2(t) dt  ,  by Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 of Davis et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (1992),  ˆun = n(ˆρLAD − ρn) →d  1  2f(0) ·  � 1  0 L(t) dK(t)  � 1  0 e−2γ(1−t)L2(t) dt  ,  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Applying the continuous mapping theorem and Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 again,  we complete the proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Denote the square root of the matrix-valued function  Λ(t) defined as in Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 by  Λ1/2(t) =  �  �λ11(t)  �λ12(t)  �λ12(t)  �λ22(t)  �  ,  0 ≤ t ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  19  Then, from Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3, we know that  �  dK(t) = �λ11(t)dB1(h(t)) + �λ12(t)dB2(h(t))  dL(t) = �λ12(t)dB1(h(t)) + �λ22(t)dB2(h(t))  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (32)  Moreover, by the time change for Itˆo integrals, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Theorem 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='7 in Øksendal  (2005), we can rewrite equations (32) as  �  dK(t) = �λ11(t)  �  h′(t)d �B1(t) + �λ12(t)  �  h′(t)d �B2(t)  dL(t) = �λ12(t)  �  h′(t)d �B1(t) + �λ22(t)  �  h′(t)d �B2(t)  ,  (33)  here �B = ( �B1, �B2) is also a 2-dimensional standard Brownian motion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' If denote  d �B(t) =  �λ11(t)  �  h′(t)d �B1(t) + �λ12(t)  �  h′(t)d �B2(t)  �  �λ2  11(t)h′(t) + �λ2  12(t)h′(t)  ,  then, by the L´evy characterization of Brownian motion, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Theorem 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 in  Øksendal (2005), we know that �B is a 1-dimensional standard Brownian motion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Notice that  �λ2  11(t)h′(t) + �λ2  12(t)h′(t) = e−2γ(1−t),  0 ≤ t ≤ 1,  hence the random variable L (γ) can be represented as  2f(0) · L (γ) =  � 1  0 e−γ(1−t)L(t) d �B(t)  �� 1  0 e−2γ(1−t)L2(t) dt  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Now, the subsequent proof will base on Theorem 1 of Rootz´en (1980) which is  restated as Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 in Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We need verify the assumptions in Theorem  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let  ϕγ(t) = 2γe−γe−γ(1−t)L(t),  0 ≤ t ≤ 1, γ > 0,  and  ψγ(t) =  �  −2γe−γ(1−t)L(t),  0 ≤ t ≤ 1, γ < 0,  then we have the following lemmas whose proofs are postponed to Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' As γ → ∞,  sup  0≤t≤1  ����  � t  0  ϕγ(s) ds  ���� →p 0  (34)  and  � 1  0  ϕ2  γ(t) dt →p N 2(0, 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (35)  Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' As γ → −∞,  sup  0≤t≤1  ����  � t  0  ψγ(s) ds  ���� →p 0  (36)  and  � 1  0  ψ2  γ(t) dt →p 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (37)  With the help of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4, Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5, and Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2, we complete the  proof of Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  20  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  Technical appendix and proofs  Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let {kn, n ≥ 1} be a sequence of positive numbers such that  kn → ∞ and kn|1 − ρ2  n| → 0 as n → ∞, then we have ρ2kn  n  → 1 and  1 − ρ2kn  n  kn(1 − ρ2n) = 1 + O(kn(1 − ρ2  n))  (38)  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Applying the Taylor’s formula, we have  log(ρ2kn  n  ) = kn log(1 + ρ2  n − 1)  = kn  �  ρ2  n − 1 − (ρ2  n − 1)2  2  + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  So ρ2kn  n  → 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Moreover, using the Taylor’s formula again, we obtain, as n → ∞  ρ2kn  n  = exp{kn(ρ2  n − 1) + O(kn(ρ2  n − 1)2)}  = 1 + kn(ρ2  n − 1) + O(k2  n(ρ2  n − 1)2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Thus the estimation (38) follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For model (1), assume that y0 = 0 and n(ρn −1) → γ for some  fixed γ ̸= 0 as n → ∞, then we have  1  n max  1≤i≤n |yi−1| →p 0, as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For any ε > 0, by the Kolmogorov’s maximal inequality,  P  � 1  n max  1≤i≤n |yi−1| > ε  �  = P  �  max  1≤i≤n  ��  i−1  �  j=1  ρi−1−j  n  ϵj  �� > nε  �  ≤  σ2  n2ε2 ·  n−1  �  j=1  ρ2(n−1−j)  n  = σ2(ρ2(n−1)  n  − 1)  n2ε2(ρ2n − 1)  → 0,  as n → ∞, which implies the desired result immediately.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Here we used the facts,  n(ρn − 1) → γ and ρn  n → eγ as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proof of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Note that there exists a sequence mn such that  mn(1 − ρn) → ∞ as n → ∞, which implies that ρmn  n  = o(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' So we can rewrite  �  1 − ρ2ny0 as follows  �  1 − ρ2ny0 =  �  1 − ρ2n  ∞  �  j=0  ρj  nϵ−j  =  �  1 − ρ2n  mn  �  j=0  ρj  nϵ−j +  �  1 − ρ2n  ∞  �  j=mn+1  ρj  nϵ−j  =: Γn,1 + Γn,2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Obviously, E(Γn,2) = 0 and  E(Γ2  n,2) = ρ2(mn+1)  n  σ2 = o(1),  LAD ESTIMATION FOR AR(1) PROCESSES  21  which immediately yield that Γn,2 →p 0 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We apply the Lindeberg-Feller  central limit theorem for the first term Γn,1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Denote ζn,j =  �  1 − ρ2nρj  nϵ−j, then  E(Γn,1) = 0 and  E(Γ2  n,1) = (1 − ρ2(mn+1)  n  )σ2 → σ2  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Hence, to complete the proof, we verify the Lindeberg condition,  for any ε > 0,  mn  �  j=0  E  �  ζ2  n,jI{|ζn,j|>ε}  �  = o(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  In fact, since 0 < ρn < 1, by dominated convergence theorem, we have  mn  �  j=0  E  �  ζ2  n,jI{|ζn,j|>ε}  �  = (1 − ρ2  n)  mn  �  j=0  ρ2j  n E  �  ϵ2  −jI{|ζn,j|>ε}  �  ≤ (1 − ρ2  n)  mn  �  j=0  ρ2j  n E  �  ϵ2  −jI{√  1−ρ2n|ϵ−j|>ε}  �  = (1 − ρ2(mn+1)  n  )E  �  ϵ2  1I{√  1−ρ2n|ϵ1|>ε}  �  = o(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Because the Lindeberg’s condition holds obviously in this case, we only  need to estimate the asymptotic variance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Noticing that ϵt have zero median, we  get E(sign(ϵt)) = 0 and  E  �� 1  √n  n  �  i=1  ρi−1  n  sign(ϵi)  �2�  =  1 − ρ2n  n  n(1 − ρ2n) → 1  as n → ∞, here we use the facts, (1 − ρn  n) ∼ n(1 − ρn) and ρn  n → 1 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Since  max  1≤i≤n |yi−1| ≤ max  �  |y0|, max  2≤i≤n |yi−1|  �  and  max  2≤i≤n |yi−1| ≤ max  2≤i≤n |ρi−1  n  y0| + max  2≤i≤n  ��  i−1  �  j=1  ρi−1−j  n  ϵj  ��,  part (1) of this lemma implies that  �  (1 − ρ2n)/n max  2≤i≤n |yi−1| ≤  �  (1 − ρ2n)/n max  2≤i≤n  ��  i−1  �  j=1  ρi−1−j  n  ϵj  �� + op(1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  By the Kolmogorov’s maximal inequality and Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, it follows that, for  any ε > 0,  P  ��  (1 − ρ2n)/n max  2≤i≤n  ��  i−1  �  j=1  ρi−1−j  n  ϵj  �� > ε  �  = P  ��  (1 − ρ2n)/n max  2≤i≤n  ��  i−1  �  j=1  ρj−1  n  ϵi−j  �� > ε  �  ≤ σ2  ε2 · 1 − ρ2n  n  n  = σ2  ε2 ·  1 − ρ2n  n  n(1 − ρn) · (1 − ρn) = o(1),  which complete the proof of part (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  22  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  Proof of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Noting that κn(1−ρn) → 0 and applying Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1,  we can show that, (1 − ρκn  n ) ∼ κn(1 − ρn) and ρκn  n  → 1 as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We omit the  remainder of the argument since it is analogous to that in the proof of Lemma  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proposition 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 are required to achieve Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' So, in the rest of  this section, we mainly make the supplement for the proofs in Section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' First of  all, we need the following modified version of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4 in Chapter 7 of Ethier  and Kurtz (1986).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1 (Ethier and Kurtz, 1986) Let Γ(t) = (γij(t))d  i,j=1 be a continuous,  symmetric, d × d matrix-valued function, defined on [0, 1], satisfying Γ(0) = 0 and  for any 0 ≤ s < t ≤ 1,  d  �  i,j=1  �  γij(t) − γij(s)  �  αiαj ≥ 0,  ∀ α = (α1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' , αd) ∈ Rd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Let {ξn  k , Fn  k , n ≥ 1, 1 ≤ k ≤ n} be an Rd-valued square-integrable martingale dif-  ference array on a completed probability space (Ω, F, P).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Denote Sn(t) = �[nt]  k=1 ξn  k  and  Θn(t) =  �  θij  n (t)  �d  i,j=1 =  [nt]  �  k=1  E  �  (ξn  k )Tξn  k |Fn  k−1  �  ,  for 0 ≤ t ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Suppose that,  E  �  sup  0≤t≤1  |Sn(t) − Sn(t−)|2�  → 0,  as n → ∞,  (39)  and for i, j = 1, 2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' , d,  E  �  sup  0≤t≤1  |θij  n (t) − θij  n (t−)|  �  → 0,  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (40)  In addition, if, for each 0 ≤ t ≤ 1 and i, j = 1, 2, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' , d,  θij  n (t) →p γij(t),  as n → ∞,  (41)  then the process Sn converges weakly to a continuous process G with independent  Gaussian increments, mean vector zero and covariance matrix Γ(t), on the Skorohod  space DRd([0, 1]) of Rd-valued cadlag paths on [0, 1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Proof of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Recall that, Fi = Fn,i = σ(ϵ1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' , ϵi) and F0 = {∅, Ω}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  For convenience, denote Xn,i = (Kn,i, Ln,i) and Xn(t) = �[nt]  i=1 Xn,i for 0 ≤ t ≤ 1,  then it is clear that {Xn,i, Fi} is an R2-valued square-integral martingale difference  array.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Note that, under these circumstances,  Θn(t) =  n  �  i=1  E  �  XT  n,iXn,i|Fi−1  �  =  n  �  i=1  E  �  XT  n,iXn,i  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  To apply Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, we first verify the non-negative definiteness of the matrix-  valued function Γ(t) defined as in (11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Clearly, for 0 ≤ s < t ≤ 1, the first principle  minor of Γ(t) − Γ(s) is positive for any γ ̸= 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' moreover, since σ2 = 1, we know  that E|ϵ1| ≤ 1 and it follows that  det(Γ(t) − Γ(s)) =  1  4γ2  �  eγ(t−s) − e−γ(t−s)�2 −  �  (t − s)E|ϵ1|  �2 ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  23  So the matrix-valued function Γ(t) is non-negative definite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Now, we check the condition (39), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  E  �  max  1≤i≤n |Xn,i|2�  → 0,  (42)  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Obviously, since ρn  n → eγ as n → ∞, we know that  max  1≤i≤n |Xn,i|2 ≤ C1  n  �  1 ∨ max  1≤i≤n ϵ2  i  �  ,  for some positive constant C1 independent of n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' For any ε > 0, by the Chebyshev’s  inequality, we can get  P( max  1≤i≤n ϵ2  i > nε) ≤ nP(ϵ2  1 > nε)  ≤ ε−(2+δ)/2n−δ/2 · E|ϵ1|2+δ → 0,  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' So  max  1≤i≤n |Xn,i|2 →p 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (43)  On the other hand, notice that, for each n,  E  ��max1≤i≤n ϵ2  i  n  �(2+δ)/2�  ≤ E|ϵ1|2+δ  nδ/2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence the family of random variables, {max1≤i≤n |Xn,i|2, n ≥ 1}, is uniformly  integrable, which, combined with (43), suggests that the condition (42) holds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We next calculate the covariance matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Observe that  [nt]  �  i=1  E  �  XT  n,iXn,i  �  =  �  1  n  �[nt]  i=1 ρ2(i−1−n)  n  tρ−1  n E|ϵ1|  tρ−1  n E|ϵ1|  1  n  �[nt]  i=1 ρ2(n−i)  n  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Therefore it is straightforward to show that, as n → ∞,  sup  0≤t≤1  |θ11  n (t) − θ11  n (t−)| = 1  n max  1≤i≤n ρ2(i−1−n)  n  → 0,  sup  0≤t≤1  |θ22  n (t) − θ22  n (t−)| = 1  n max  1≤i≤n ρ2(n−i)  n  → 0,  sup  0≤t≤1  |θ12  n (t) − θ12  n (t−)| = sup  0≤t≤1  |θ21  n (t) − θ21  n (t−)| = 0,  and  Θn(t) → Γ(t) =  �  e−2γ  2γ (e2γt − 1)  tE|ϵ1|  tE|ϵ1|  e2γ  2γ (1 − e−2γt)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence, by Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1, the process Xn converges weakly to a continuous process  X = (X(t), 0 ≤ t ≤ 1) which has independent Gaussian increments, zero mean  vector and covariance matrix Γ(t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We now turn to the proof of the equation (30).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' From the proof of Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='1  in Chapter 7 of Ethier and Kurtz (1986), we know that the limit process X can be  represented by  XT(t) =  � t  0  Λ1/2(s) dBT(h(s)),  0 ≤ t ≤ 1,  24  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  where Λ(·) is a non-negative definite matrix-valued function, B = (B1, B2) is a  2-dimensional standard Brownian motion, and  h(t) = γ11(t) + γ22(t),  0 ≤ t ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  In fact, the entries λij(·) of Λ(·) are the solutions of the following equations,  �  �  �  �  �  �  �  �  �  γ11(t) =  � t  0 λ11(s) dh(s),  γ22(t) =  � t  0 λ22(s) dh(s),  γ12(t) =  � t  0 λ12(s) dh(s),  γ21(t) =  � t  0 λ21(s) dh(s).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  (44)  Solving (44), we can get  λ11(t) =  e−2γ(1−t)  e2γ(1−t) + e−2γ(1−t) = 1 − tanh(2γ(1 − t))  2  ,  λ22(t) =  e2γ(1−t)  e2γ(1−t) + e−2γ(1−t) = 1 + tanh(2γ(1 − t))  2  ,  λ12(t) =λ21(t) =  E|ϵ1|  e2γ(1−t) + e−2γ(1−t) =  E|ϵ1|  2 cosh(2γ(1 − t)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence we complete the proof of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='2 (Rootz´en, 1980) Let (B(t), 0 ≤ t ≤ 1) be a standard Brownian  motion with respect to the filtration (Ft, 0 ≤ t ≤ 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Suppose (φn(t), 0 ≤ t ≤ 1)n≥1  is a sequence of random functions which is adapted to the filtration (Ft, 0 ≤ t ≤ 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  If  sup  0≤t≤1  ����  � t  0  φn(s) ds  ���� →p 0,  as n → ∞,  and  � 1  0  φ2  n(t) dt →p τ,  as n → ∞,  for some random variable τ such that τ > 0 a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=', then  � 1  0 φn(t) dB(t)  �� 1  0 φ2n(t) dt  →d N (0, 1),  as n → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 (Graversen and Peskir, 2000) Let (V (t), t ≥ 0) be the Ornstein-  Uhlenbeck process solving  dV (t) = −βV (t)dt + dB(t)  with V (0) = 0, where β > 0 and (B(t), t ≥ 0) is a standard Brownian motion, then  there exist universal positive constants c0, c1 such that, for all stopping times τ of  (V (t), t ≥ 0),  c0  √β E  �  log(1 + βτ) ≤ E  �  max  0≤t≤τ |V (t)|  �  ≤ c1  √β E  �  log(1 + βτ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  25  Proof of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Since  sup  0≤t≤1  ����  � t  0  ϕγ(s) ds  ���� ≤  � 1  0  |ϕγ(t)| dt,  it is enough to show  � 1  0 |ϕγ(t)| dt →p 0 as γ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Notice that, from Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3,  L(t) ∼ N  �  0, e2γ(1 − e−2γt)  2γ  �  ,  so  E  � 1  0  |ϕγ(t)| dt = 2γe−γ  � 1  0  e−γ(1−t)E|L(t)| dt  =  �  4γ/πe−γ  � 1  0  �  e2γt − 1 dt  ≤  �  4/(πγ)(1 − e−γ) → 0,  as γ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  By the Markov’s inequality, this establishes the equation (34).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  We next prove equation (35).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Firstly, using integration by parts, we can get  � 1  0  ϕ2  γ(t) dt = 4γ2e−4γ  � 1  0  e2γtL2(t) dt  = 2γe−4γ  � 1  0  L2(t) de2γt  = 2γe−4γ  �  L2(1)e2γ −  � 1  0  e2γt dL2(t)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Furthermore, since  �λ2  12(t)h′(t) + �λ2  22(t)h′(t) = e2γ(1−t),  0 ≤ t ≤ 1,  the Itˆo’s formula, together with equation (33), yields that  dL2(t) = 2L(t) dL(t) + e2γ(1−t) dt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Therefore  � 1  0  ϕ2  γ(t) dt = 2γe−2γL2(1) − 2γe−2γ − 4γe−4γ  � 1  0  e2γtL(t) dL(t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Noticing that  L(1) ∼ N  �  0, e2γ − 1  2γ  �  ,  we have  2γe−2γL2(1) =d  ��  1 − e−2γN (0, 1)  �2 →p N 2(0, 1),  as γ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' In addition,  E  �  4γe−4γ  � 1  0  e2γtL(t) dL(t)  �2  = 16γ2e−6γ  � 1  0  e2γtEL2(t) dt  = 8γe−4γ  � 1  0  (e2γt − 1) dt ≤ 4e−2γ → 0,  26  NANNAN MA, HAILIN SANG, AND GUANGYU YANG  as γ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' It follows from the Chebyshev’s inequality that  4γe−4γ  � 1  0  e2γtL(t) dL(t) →p 0,  as γ → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence we achieve the equation (35).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The proof is complete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Proof of Lemma 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' We first show that the equation (36) holds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Let  dB∗(t) =  �λ12(t)  �  h′(t)d �B1(t) + �λ22(t)  �  h′(t)d �B2(t)  �  �λ2  12(t)h′(t) + �λ2  22(t)h′(t)  ,  then, by the L´evy characterization of Brownian motion, B∗ is a 1-dimensional  standard Browinan motion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Since  �λ2  12(t)h′(t) + �λ2  22(t)h′(t) = e2γ(1−t),  0 ≤ t ≤ 1,  the equation (33) implies that  dL(t) = eγ(1−t)dB∗(t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence, by the Itˆo’s formula, we have  � t  0  ψγ(s) ds =  �  −2γe−γ  � t  0  eγsL(s)ds  =  √−2γe−γ  γ  �  eγtL(t) −  � t  0  eγs dL(s)  �  =  √−2γ  γ  �� t  0  eγ(t−s) dB∗(t) − B∗(t)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Therefore  sup  0≤t≤1  ����  � t  0  ψγ(s) ds  ���� ≤  � 2  −γ  �  sup  0≤t≤1  ����  � t  0  eγ(t−s) dB∗(t)  ���� + sup  0≤t≤1  |B∗(t)|  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Obviously,  � 2  −γ  �  sup  0≤t≤1  |B∗(t)|  �  →p 0,  as γ → −∞ and Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='3 shows that  E  �� 2  −γ sup  0≤t≤1  ���  � t  0  eγ(t−s) dB∗(t)  ���  �  ≤ c1  �  2 log(1 − γ)  −γ  → 0,  as γ → −∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' By the Markov’s inequality again, we achieve the equation (36).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Finally, we verify the equation (37).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Notice that  dL2(t) = 2L(t) dL(t) + e2γ(1−t) dt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  It follows that � 1  0  ψ2  γ(t) dt = −L2(1) + 1 + 2e−2γ  � 1  0  e2γtL(t) dL(t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Since  L(t) ∼ N  �  0, e2γ(1 − e−2γt)  2γ  �  ,  we have  L2(1) →p 0,  as γ → −∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  LAD ESTIMATION FOR AR(1) PROCESSES  27  Moreover,  E  �  2e−2γ  � 1  0  e2γtL(t) dL(t)  �2  = 4e−4γ  � 1  0  e4γte2γ(1−t)EL2(t) dt  = 2  γ  � 1  0  (e2γt − 1) dt → 0,  as γ → −∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' It concludes from the Chebyshev’s inequality that  2e−2γ  � 1  0  e2γtL(t) dL(t) →p 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Hence we obtain the equation (37).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The proof is complete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  □  Acknowledgment  The authors would like to express their sincere gratitude to the anonymous  referees and AE for helpful comments which surely lead to an improved presentation  of this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' The authors are very grateful to Huarui He, Hui Jiang, Feng Li,  Yu Miao, Shaochen Wang and Qingshan Yang for the helpful discussions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content=' Hailin  Sang’s work was partially supported by the Simons Foundation grant 586789, USA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Guangyu Yang’s work was partially supported by the Foundation of Young Scholar  of the Educational Department of Henan Province grant 2019GGJS012, China.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Data Availability Statement: The data that support the findings of this study are  available from the corresponding author upon reasonable request.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
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+page_content='  Email address: 1055165454@qq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
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+page_content=' Sang) Department of Mathematics, University of Mississippi, University, MS,  38677, USA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
+page_content='  Email address: sang@olemiss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/f9E0T4oBgHgl3EQfXQDJ/content/2301.02291v1.pdf'}
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+Draft version January 6, 2023
+Typeset using LATEX preprint style in AASTeX63
+Fragmentation of the High-mass “Starless” Core G10.21-0.31: a Coherent
+Evolutionary Picture for Star Formation
+Wenyu Jiao,1, 2 Ke Wang,1 Thushara G.S. Pillai,3 Tapas Baug,4 Siju Zhang,1 and
+Fengwei Xu1, 2
+1Kavli Institute for Astronomy and Astrophysics, Peking University, Haidian District, Beijing 100871, People’s
+Republic of China
+2Department of Astronomy, School of Physics, Peking University, Beijing, 100871, People’s Republic of China
+3Institute for Astrophysical Research, Boston University, 725 Commonwealth Avenue, Boston MA, 02215, USA
+4S. N. Bose National Centre for Basic Sciences, Block-JD, Sector-III, Salt Lake City, Kolkata 700106, India
+ABSTRACT
+G10.21-0.31 is a 70 µm-dark high-mass starless core (M > 300 M⊙ within r < 0.15
+pc) identified in Spitzer, Herschel, and APEX continuum surveys, and is believed to
+harbor the initial stages of high-mass star formation. We present ALMA and SMA
+observations to resolve the internal structure of this promising high-mass starless core.
+Sensitive high-resolution ALMA 1.3 mm dust continuum emission reveals three cores
+of mass ranging 11-18 M⊙, characterized by a turbulent fragmentation. Core 1, 2, and
+3 represent a coherent evolution at three different evolutionary stages, characterized
+by outflows (CO, SiO), gas temperature (H2CO), and deuteration (N2D+/N2H+). We
+confirm the potential to form high-mass stars in G10.21 and explore the evolution path
+of high-mass star formation. Yet, no high-mass prestellar core is present in G10.21.
+This suggests a dynamical star formation where cores grow in mass over time.
+Keywords: massive stars (732); Infrared dark clouds (787); protostars (1302); star for-
+mation (1569)
+1. INTRODUCTION
+High-mass stars play essential roles in the evolution of their host galaxy via their radiation, stellar
+wind and supernovae events. However, compared with their low-mass counterparts, the formation
+mechanism of high-mass stars is poorly understood (Tan et al. 2014; Motte et al. 2018).
+There are two mainstream models describing the forming process of high-mass stars: the monolithic
+collapse model (McKee & Tan 2003) and the competitive accretion model (Bonnell et al. 2001). In
+the monolithic collapse model, the final stellar mass is pre-assembled in a single high-mass turbulent
+core. Turbulence can effectively resist self-gravity until the accretion mass is large enough. So this
+model requires the existence of high-mass starless cores. In the competitive accretion model, high-
+mass stars begin as low-mass cores (∼ 1 M⊙) and most of the stellar mass comes from the subsequent
+Corresponding author: Ke Wang
+kwang.astro@pku.edu.cn
+arXiv:2301.02070v1  [astro-ph.GA]  5 Jan 2023
+
+2
+Jiao, Wang et al.
+accretion process. Different from Bondi-Hoyle-Lyttleton-like core accretion model, recent studies also
+propose some new accretion mechanisms such as gravitationally driven cloud inflow (Smith et al. 2009;
+Hartmann et al. 2012) or supersonic turbulence driven inflow (Padoan et al. 2020). However, both
+the mechanisms are yet to get enough observational evidence.
+In order to distinguish the different forming processes of high-mass stars, it is important to probe
+the initial conditions towards the birthplace of high-mass star forming regions. Infrared-dark clouds
+(IRDCs), often considered as the cradle of massive stars, provide ideal laboratories to study the
+formation of high-mass stars (Bergin & Tafalla 2007). In recent years, many high-resolution and
+high-sensitivity observations have revealed the physical properties of the cores embedded in IRDCs,
+suggesting that most of the clumps in IRDCs have left the starless stage and begun star formation
+activities (e.g., Zhang et al. 2009, 2015; Wang et al. 2011, 2014; Sanhueza et al. 2013, 2019; Svoboda
+et al. 2019; Pillai et al. 2019; Barnes et al. 2021).
+Blind surveys of continuum emission at far-infrared and (sub)millimeter wavelengths towards the
+Galactic plane reveal the dense structures at different evolutionary stages (e.g., Schuller et al. 2009;
+Molinari et al. 2010; Aguirre et al. 2011; Eden et al. 2017), offering good data sets for us to search for
+the cradle of high-mass star forming regions. Yuan et al. (2017) have selected 463 high-mass starless
+clump candidates based on The APEX Telescope Large Area Survey of the Galaxy (ATLASGAL)
+catalog (Schuller et al. 2009). Compared with other high-mass starless clump catalogs (e.g., Tacken-
+berg et al. 2012; Traficante et al. 2015; Svoboda et al. 2016), this catalog has the largest sky coverage.
+Besides the commonly adopted infrared-dark criteria, this catalog also ruled out sources associated
+with reported star-forming indicators and performed extra visual checks on each source, which made
+it the most reliable high-mass starless clump candidate catalog. Detailed studies towards this sample
+can help us reveal the initial conditions of high-mass star forming regions.
+G10.21-0.31
+Yuan et al. (2017) found twenty high-mass starless core candidates with an equivalent radius smaller
+than 0.15 pc. G10.21-0.31 (hereafter G10.21) is the second most massive source in the sample. Figure
+1 shows the infrared emission of G10.21 at different wavelengths. This source is dark at near-infrared,
+mid-infrared, far-infrared up to 70 µm, and transitions to be bright at longer wavelengths (250/870
+µm bright). Located at a distance of 3.1 kpc, this high-mass prestellar core candidate contains 314
+M⊙ gas within an equivalent radius of 0.13 pc (Yuan et al. 2017). The luminosity of the target is
+667 L⊙, leading to a relatively low luminosity-to-mass ratio (2.13 L⊙/M⊙, Yuan et al. (2017)). The
+deuterium fraction of NH3 in this source is higher than 30%, suggesting it is at a very young age
+(Pillai et al. 2007). The dust temperature of G10.21 is 16.6 K under 36.4′′ resolution (Yuan et al.
+2017) and the kinetic temperature derived from NH3 is 18.5 K under 40′′ resolution (Wienen et al.
+2012). Because of its small size, low temperature, low luminosity-to-mass ratio, high mass and high
+deuterium fraction, this source is an ideal object to study the initial conditions of high-mass star
+formation. In addition, it is located at the edge of the HII region G010.232-0.301 (Anderson et al.
+2011), which may suffer strong environmental feedback. Zhang et al. (2021) compared four pairs of
+high-mass starless clumps (near or far from HII regions) and found that this source is more likely to
+be affected by the surrounding HII regions. Hence, exploring the initial star formation processes of
+G10.21 is of great interest.
+The paper is organized as follows. We describe the observations in Section 2 and show the main
+results in Section 3. In Section 4, we discuss potential bias from temperature correction and the gas
+
+3
+Figure 1. Overview of the high-mass starless core G10.21. Four panels show images at different wavelengths
+adapted from Yuan et al. (2017). (a) Three color image with emission at 8.0, 4.5, and 3.6 µm rendered in
+red, green, and blue, respectively. (b) Spitzer 24 µm emission. (c) Herschel 70 µm emission. (d) APEX
+870 µm emission (red contours) with levels of [0.3, 0.4, 0.5, 0.7, 0.9, 1.3, 1.8, 2.5, 4, 7] Jy/beam overlaid on
+Herschel 250 µm map (color). The white cross marks the peak position of 870 µm source, and the white
+ellipse describes the source size based on the major and minor half-intensity axes.
+fragmentation mechanism in G10.21. We also discuss the chemical evolution in star formation to
+investigate the possibility of chemical clocks. In addition, we study the potential to form high-mass
+stars and describe a simple possible evolutionary picture of G10.21. Finally, we give the summary of
+this work in Section 5.
+2. OBSERVATIONS AND DATA REDUCTION
+2.1. ALMA Band 6 Observations
+G10.21 was observed with ALMA in Band 6, as part of the Cold Cores with ALMA (CoCoA) survey
+(Project ID: 2016.1.01346.S, PI: Thushara G.S. Pillai). In this work, we combine the data of the 12
+m main array and the 7m Atacama Compact Array (ACA). The observations had four wide spectral
+windows with a bandwidth of 1.875 GHz for 12 m array and 2 GHz for 7 m array centered on 216.89,
+218.76, 231.12, 232.89 GHz. The spectral windows have a uniform channel width of 244.14 kHz (∼
+0.32 km s−1 at 230 GHz). The phase reference center was R.A. (J2000) = 18:09:20.7 and Decl. (J2000)
+= -20:15:04.0. Quasars J1832-2039 and J1924-2914 were used for phase and bandpass calibration.
+For the 12 m array observations, the source was observed on March 31, 2017 and May 14, 2018. The
+maximum recoverable scale was 13.7′′ and the primary beam size was 25.9′′. The integration time
+was approximately 1.5 minutes. Titan was used for flux calibration. For the 7 m array observations,
+the source was observed in July-September, 2017. The maximum recoverable scale was 36.4′′ and the
+primary beam size was 44.4′′. The integration time was approximately 9 minutes. J1733-1304 was
+used for flux calibration.
+Data reduction was performed using CASA software package version 5.6.1 (McMullin et al. 2007).
+For continuum data, we use the split task to obtain line-free channels in each spectral window.
+The visibility data of 12 m array and 7 m array from the four spectral windows were combined in
+CASA using concat task. The combined 12 + 7 m continuum visibility data was cleaned using tclean
+task, with a Briggs’s robust weighting of 0.5 and a cell size of 0.3′′. The synthesized beam size is
+1.7′′ × 1.0′′ (0.03 pc × 0.02 pc at 3.1 kpc distance), with a position angle of −76◦. The RMS noise of
+
+Myr sr-1
+Myr sr-1
+Myr sr-1
+135
+393
+1142
+5469
+9287
+15769
+5453
+9591
+16867
+G010.2144-0.3051
+red: 8.0 μm
+(a)
+(b)
+24 μm
+(c)
+70 μm
+250 μm
+d
+-20°14'
+green: 4.5 μm
+blue:3.6 μm
+(J2000)
+15'
+O
+Dec
+16'
+24s
+21s
+18s 18h09m15s
+RA (J2000)4
+Jiao, Wang et al.
+Table 1. Summary of Spectral Line Information
+Line
+Transition
+Rest Freq.
+Eu/k
+Velocity Resolution
+Beam Size
+(GHz)
+(K)
+(km s−1)
+(′′×′′)
+DCO+
+J=3 − 2
+216.112580
+20.74
+0.34
+1.98×1.14
+SiO
+J=5 − 4
+217.104980
+31.26
+0.34
+1.98×1.14
+DCN
+J=3 − 2
+217.238530
+20.85
+0.34
+1.98×1.14
+H2CO
+JKa,Kc=30,3 − 20,2
+218.222192
+20.96
+0.34
+1.97×1.12
+H2CO
+JKa,Kc=32,2 − 22,1
+218.475632
+68.09
+0.34
+1.97×1.12
+H2CO
+JKa,Kc=32,1 − 22,0
+218.760066
+68.11
+0.33
+1.96×1.12
+CO
+J=2 − 1
+230.538000
+16.60
+0.32
+1.83×1.07
+N2D+
+J=3 − 2
+231.321828
+22.20
+0.32
+1.82×1.07
+the continuum image measured in an emission-free region is about 0.5 mJy/beam (∼0.15 M⊙ with a
+16.6 K dust temperature at 3.1 kpc). For spectral line, the combined 12 + 7 m line cube was cleaned
+using tclean task after removing the continuum emission using uvcontsub task, with a Briggs robust
+weighting of 0.5 and a cell size of 0.3′′. The threshold is 2σ=0.025 Jy and the maximum number of
+iteration (niter) is 10000. Multi-scale Clean is used for CO, SiO and H2CO lines to better recover
+extended emission and scales are set to be [0, 5, 15]. We use auto-multithresh algorithm and the
+parameters are equal to the standard value for 12m + 7m combined data in official guides1. The
+synthesized beam size of different lines is similar to the beam size of continuum image but has a
+small difference because of the frequency offset. We summarize the spectral line information used in
+our analysis in Table 1. The typical noise level is ∼150 mK after converting the cube to brightness
+temperature units.
+2.2. SMA Observations
+G10.21 was observed by SMA (project ID: 2008A-S075, PI: Thushara G.S. Pillai). The observations
+were performed with the LO tuned at 225.4 GHz for N2D+ (J = 3 − 2) on August 24th, 2008 and
+275.1 GHz for N2H+ (J = 3 − 2) on August 30th, 2008. Gain calibration was performed by periodic
+observations of quasars NRAO530 and J1911-201. Uranus was used for flux calibration. 3C454.3
+was used for bandpass calibration. For N2D+ observation, the on-source integration time was 98
+minutes. The synthesized beam size was 6.4′′ × 3.3′′ (0.10 pc × 0.05 pc), with a position angle of
+23◦. For N2H+ observation, the on-source integration time was 24 minutes. The synthesized beam
+size was 9.8′′ × 3.2′′ (0.15 pc × 0.05 pc), with a position angle of −2◦. To compare the two SMA
+cubes directly, we convolved the image to the same resolution and reprojected them into the same
+grid. The final synthesized beam was 9.8′′ × 4.3′′ (0.15 pc × 0.06 pc), with a position angle of −2◦.
+The typical noise levels were 0.10 K and 0.03 K for N2H+ and N2D+ spectra, respectively.
+3. RESULTS
+3.1. 1.3 mm Compact Continuum Sources
+1 see details in https://casaguides.nrao.edu/index.php?title=Automasking Guide
+
+5
+Figure 2. ALMA 1.3 mm continuum image of G10.21 shown in color after primary beam correction. The
+cyan ellipse represents the deconvolved image size of the cores. The white contours show emission at 870
+µm from the ATLASGAL survey with the same levels in Figure 1. The black contours show continuum
+emission at levels of [6, 9, 12, ...]σ, where σ equals to 5 × 10−4 Jy/beam. The blue ellipse in the bottom left
+marks synthesized beam.
+The 1.3 mm continuum map (centered at 224.92 GHz) is shown in Figure 2. We use Dendrogram
+algorithm2 on the continuum image without primary beam correction to identify dense cores. The
+min value is set to be 3σ, where σ is the RMS noise of the continuum image. The min delta is set to
+be 1.5σ and the min npix equals to 21 (The number of pixels within the beam area). To accurately
+derive the position, flux density, size information of these cores, we make use of imfit function in
+CASA on the 1.3 mm continuum image after primary beam correction. We identified three compact
+cores in this source and the detailed observed properties are listed in Table 2. All three cores are
+detected with high signal-to-noise ratios (S/N >6).
+2 https://dendrograms.readthedocs.io/en/stable/
+
+0.010
+-20°14'50"
+0.008
+Core 1
+0.006
+Core 3
+15'00"
+Dec (ICRS)
+0.004
+Jy/beam
+Core
+0.002
+10"
+0.000
+0.002
+20"
+0.1 pc
+-0.004
+18h09m22s
+21s
+20s
+RA (ICRS)6
+Jiao, Wang et al.
+Table 2. Core Observed Properties
+Core
+RA(J2000)
+Dec(J2000)
+Sizea
+Size
+PA
+Speak
+Score
+Tdb
+Mgas
+nH2
+(h:m:s)
+(d:m:s)
+(′′×′′)
+(pc×pc)
+(deg)
+(mJy/beam)
+(mJy)
+(K)
+(M⊙)
+(cm−3)
+1
+18:09:20.33
+-20:14:55.6
+4.1×3.0
+0.06×0.04
+106
+4.6
+37.2
+16.6
+11.5
+2.6 × 106
+2
+18:09:20.37
+-20:15:05.0
+2.8×2.0
+0.04×0.03
+128
+10.6
+45.3
+16.6
+14.0
+1.0 × 107
+3
+18:09:20.76
+-20:15:00.4
+3.5×2.7
+0.05×0.04
+13
+8.3
+55.6
+16.6
+17.2
+5.9 × 106
+T c
+H2CO
+(K)
+1
+16.6
+11.5
+2.6 × 106
+2
+83.0
+2.1
+1.5 × 106
+3
+67.7
+3.2
+1.1 × 106
+T d
+typical
+(K)
+1
+16.6
+11.5
+2.6 × 106
+2
+40
+4.7
+3.6 × 106
+3
+40
+5.8
+2.0 × 106
+a: Core size deconvolved from synthesized beam.
+b: Dust temperature of G10.21 adopted from Yuan et al. (2017).
+c: Rotational temperature by fitting the para − H2CO lines, see more details in Section 4.1.
+d: Typical dust temperature for protostars, see more details in Section 4.1.
+We estimate the core mass of three identified cores based on the dust continuum flux following the
+equation
+Mgas = η
+Fνd2
+Bν(Td)κν
+(1)
+where Mgas is the gas mass, η = 100 is the gas-to-dust ratio, Fν is the continuum flux at frequency
+ν, d is the kinetic distance of the source, Bν (Td) is the Planck function at the dust temperature, and
+κν = 10 (ν/1.2 THz)β cm2 g−1 represents the dust opacity (Hildebrand 1983). In our calculation, we
+use the value of Td = 16.6 K derived for the whole region with 36.4′′ resolution in Yuan et al. (2017)
+and adopt the dust opacity index β = 1.5. If we adopt the value of 0.9 cm2 g−1 for dust opacity at
+1.3 mm with a volume density of 106 cm−3 density from Ossenkopf & Henning (1994), the derived
+gas masses from Core 1 to Core 3 will be 10.4, 12.6, 15.5 M⊙, leading to about 10% difference to the
+final results.
+The number density of each core is calculated assuming the sources to be spherically symmetric
+using the following equation:
+nH2 =
+Mgas
+4
+3πµmH r3
+eff
+(2)
+where µ (µ = 2.37) is the mean molecular weight per free particle, considering H2, He, and ignoring
+the number of heavier elements (Kauffmann et al. 2008), mH is the mass of a hydrogen atom, and
+reff = d
+2
+�
+ΘmajΘmin is the equivalent radius of each core. The mean number density of cores is in
+
+7
+Figure 3. Moment-0 maps of different molecular lines after primary beam correction. We cut the image
+at the primary beam response of 0.2 for CO and SiO, and 0.5 for other lines, leading to little differences in
+field of view. The integrated velocity range is from -15 km s−1 to 30 km s−1 for CO and SiO, 4 km s−1 to
+20 km s−1 for three para-H2CO lines, and from 8 km s−1 to 16 km s−1 for other lines. The white contours
+show continuum emission at levels of [6, 12, 24, 48]σ, where σ equals to 5×10−4 Jy/beam. The top-left blue
+ellipse in the bottom left marks synthesized beam.
+
+Kkm s-1
+Kkm s-1
+Kkm s-1
+30
+60
+06
+120
+150
+5
+10
+15
+20
+5
+10
+15
+20
+20°14'45"
+(a) co
+(b) Sio
+(c) H2CO 30,3 -20,2
+Dec (ICRS)
+15'00"
+15'
+1809-21
+20°
+1809-21
+20°
+1809-21
+20°
+RA (ICRS)
+RA (ICRS)
+RA (ICRS)
+Kkm s-i
+Kkm s-i
+Kkm s-1
+1.53.04.5
+6.0
+7.5
+9.0
+1.53.0
+4.5
+6.0
+7.5
+9.0
+0.5
+1.0
+1.5
+2.0
+2.5
+20°14'45"
+(d) H2CO 32,2 - 22,1
+(e) H2CO 32,1- 22. 0
+f)DCO
+Dec (ICRS)
+15'00"
+15'
+109-21-
+20°
+1809-21
+20°
+109-21-
+20°
+RA (ICRS)
+RA (ICRS)
+RA (ICRS)
+Kkm s-i
+0.9
+1.8
+2.7
+3.6
+4.5
+0.6
+1.2
+1.8
+2.4
+3.0
+20914'45"
+(g)DCN
+(h) N2D
+Dec (ICRS)
+15'00"
+15"
+109-21
+20°
+18109m21
+20°
+RA (ICRS)
+RA (ICRS)8
+Jiao, Wang et al.
+range from 106 to 107 cm−3 as listed in Table 2. The mean number density of Core 2 and Core 3 is
+several times larger than Core 1.
+The derived core mass ranges from 11 M⊙ to 18 M⊙. Here we discuss the uncertainties of derived
+mass. We can get the uncertainty of continuum flux and effective radius in imfit function (∼ 10%).
+The typical uncertainties of gas-to-dust ratio and dust opacity are 23% and 28 % derived in Sanhueza
+et al. (2017). Using the online Parallax-Based Distance Calculator3, the uncertainty in the distance
+is 7%. The uncertainty of dust temperature is taken to be 10 %. Taking all these things into account,
+we estimate a mass and number density uncertainty of ∼ 42% and ∼ 56%.
+3.2. Molecular Line Emission
+Different molecular lines trace different physical conditions, providing useful information about
+dense cores and their surrounding environments. The ALMA observations cover a total of ∼8 GHz
+bandwidth in four spectral windows, detecting many molecular lines in dense cores. We show the
+spectra of three identified cores and discuss their chemical differential in Appendix A. The differential
+of line richness suggests an evolution path from Core 1 to Core 3.
+Figure 3 shows the integrated intensity map of molecular lines used in our analysis. Since CO, SiO
+and H2CO trace more extended emission, deuterated species are good dense gas tracers. We cut the
+image at the primary beam response of 0.2 for CO, SiO, H2CO, and 0.5 for deuterated molecular
+lines, leading to little differences in field of view. The integrated velocity ranges from -15 km s−1 to
+30 km s−1 for CO and SiO, 4 km s−1 to 20 km s−1 for three para-H2CO lines, and from 8 km s−1 to
+16 km s−1 for three deuterated molecular lines (DCN, DCO+, N2D+).
+The spatial distribution of CO and SiO is mainly associated with outflow activities and less as-
+sociated with continuum emissions. Note that SiO emission can also be emitted by accretion disks
+(Maud et al. 2018). In our analysis, we exclude the possibility because of the large spatial scales
+(> 104 AU). Previous studies suggest H2CO lines can be used to trace not only the compact cores
+but also outflows (e.g., Tychoniec et al. 2019; Beuther et al. 2021), which is consistent with our
+observations. The spatial distribution of three deuterated lines mainly agrees with the continuum
+emission, indicating that the three molecular lines are good dense gas tracers.
+3.3. Outflow Properties
+The outflow signatures of three compact cores are revealed by CO (2-1) and SiO (5-4) emission.
+To identify the outflows, we concentrate on blueshifted and redshifted CO and SiO emission relative
+to the systematic velocity of the sources. Figure 4 shows the velocity-integrated emission map and
+identified outflow lobes of CO (2-1) and SiO (5-4). The detailed process of outflow identification for
+the complex CO emission is shown in Appendix B. A slight difference has been noted in the number
+and orientation of the identified lobes using these two tracers. Note that CO and SiO have different
+excitation temperatures and thus, a slight difference in the identified lobes is possible.
+We find
+explicit bipolar outflow activities towards Core 2 and Core 3, indicating the two cores are associated
+with ongoing star formation activities. We also find more than one group of outflows associated with
+Core 3, which implies that there may be multiple driving sources within this core. In addition, we
+find a possible weak CO outflow around Core 1 that is however lower than the velocity range we had
+3 http://bessel.vlbi-astrometry.org/bayesian
+
+9
+Figure 4. CO and SiO outflows of G10.21 after primary beam correction. The grayscale background image
+shows the ALMA 1.3 mm continuum emission. The blue ellipse in the bottom-left marks the beam area
+of the continuum. The cyan ellipse marks the position of the cores. (a): CO outflows. The blue and red
+contours show the blueshifted and redshifted CO emission integrated over [-7, 8] km s−1 and [14, 29] km s−1,
+at levels of [3, 15, 30, 50, 100, 200]σ and [6, 15, 30, 50, 100, 200]σ, where σ equals to 2 K km s−1. (b): SiO
+outflows. The blue and red contours show the blueshifted and redshifted SiO emission integrated over [-10,
+10] km s−1 and [14, 34] km s−1, at levels of [3, 6, 9, 12, ...]σ, where σ equals to 1 K km s−1. The blue and
+red arrows mark the directions of outflows.
+defined for characterizing outflow emission. Also, it may be attributed to side lobe contamination or
+an extension of outflow lobe o3a. Therefore, the evolutionary phase of Core 1 is uncertain.
+Since the emission from CO lobes is tangled and it is difficult to distinguish them from each other,
+we use SiO data to estimate the outflow parameters only for those lobes that are identified in both
+tracers. For the red lobe of outflow 3a, we assume that the observed emission is associated with Core
+3 rather than Core 1 because of two possible reasons. First, no blue lobes are identified for Core 1 in
+SiO and second, the intensity of the blue lobe of 3a is strong enough to make us consider that the red
+emission only corresponds to the red lobe of 3a. We calculate the SiO column density according to
+the equation from Mangum & Shirley (2015). Assuming that the beam filling factor equals to 1, SiO
+emission is optically thin, the temperature of the background source is negligible, Rayleigh–Jeans
+approximation and local thermodynamic equilibrium (LTE) conditions can be applied, we can get
+the following equation:
+Ntot = (
+3kB
+8π3νSµ2
+d
+) ( Qrot
+gJgKgI
+) exp( Eu
+kBTex
+)
+�
+TBdv
+(3)
+where kB is the Boltzmann constant, ν is the rest frequency of the SiO (5-4) transition, S is the line
+strength, µd is the permanent dipole moment of the molecule, Qrot is the partition function of the
+molecule, gi are the degeneracies, Eu is the energy of the upper energy level, Tex is the excitation
+temperature. Here we can simplify the equation:
+NSiO
+�
+cm−2�
+= 1.54 × 1010 (Tex + 0.347) exp
+�31.26
+Tex
+� �
+TBdv
+(4)
+
+a) co
+BO0'0
+20814'50″
+0.006
+0.004
+15'00"
+Dec (ICRS)
+Jy/beam
+3b
+2a
+0.002
+10"
+2.8
+0.000
+0.002
+20"
+0.004
+1809±22.021.5s
+21.0s
+20.5s
+20.0s
+19.5s
+RA (ICRS)0.010
+(b) SiOp
+20°14'50"
+3c+
+B00'0
+0.006
+15'00"
+Core
+3h
+Dec (ICRS)
+0.004
+Jy/beam
+3b
+28
+2a
+0.002
+10"
+0.000
+0.002
+20"
+0.004
+1809±22.021.5s
+21.0s
+20.5s
+20.0s
+19.5s
+RA (ICRS)10
+Jiao, Wang et al.
+In our calculation, we assume Tex ≈ Tkin,NH3=18.5 K. Then we can derive the outflow parameters
+following the similar procedure reported in Wang et al. (2011) and Baug et al. (2021):
+Mout =
+d2
+�
+SiO
+H2
+�µmH
+�
+Ω
+NSiO (Ω′) dΩ′
+(5)
+Pout = Moutv ×
+1
+cos i
+(6)
+Eout = 1
+2Moutv2 ×
+1
+cos2i
+(7)
+tdyn = lflow
+vLobe
+× cos i
+sin i
+(8)
+˙Mout = Mout
+tdyn
+× sin i
+cos i
+(9)
+where d is the kinetic distance to G10.21, which is taken to be 3.1 kpc (Yuan et al. 2017),
+�
+SiO
+H2
+�
+is
+the SiO abundance relative to H2. In our calculation, we set the value to be 1.8 × 10−10, which is
+the average SiO abundance for infrared-quiet sources in Csengeri et al. (2016). Note that the SiO
+abundance may be enhanced in outflow regions and vary greatly in different regions, which may cause
+a few orders of magnitude difference from 10−12 to 10−8 (e.g., Li et al. 2019b; Lu et al. 2021). The v is
+the velocity of the outflow relative to the systematic velocity of driving source in the line of sight and
+the systematic velocity is determined by N2D+ line fitting (11.5 km s−1 for Core 2 and 12.3 km s−1
+for Core 3). lflow is the maximum distance between the extent of outflow lobe and the central source
+projected to the plane of sky. In addition, vlobe is the maximal velocity offset in the line of sight of
+the outflow lobe relative to the driving source and i is the inclination angle between the outflow jet
+and the line of sight, which is set to be an average value of 57.3◦ assuming all orientations are equally
+favorable (see Bontemps et al. 1996 for detailed calculation).
+Table 3. Derived Outflow Parameters
+Parametera
+o2a
+o3a
+o3b
+o3cb
+Blue
+Red
+Blue
+Red
+Blue
+Red
+Blue
+v (km s−1)
+[-11.9, 10]
+[13.1, 24.9]
+[-4.1, 9.0]
+[13.1, 21.8]
+[-0.1, 12.0]
+[13.1, 25.9]
+[-5.1, 10]
+Mout (M⊙)
+0.58
+0.38
+9.31
+3.81
+1.09
+2.93
+2.79
+Pout (M⊙ km s−1)
+13.37
+4.98
+152.2
+32.43
+10.71
+30.40
+49.13
+Eout (M⊙ km2 s−2)
+194.0
+38.28
+1450
+171.7
+73.76
+220.2
+509.0
+lflow (pc)
+0.04
+0.05
+0.31
+0.17
+0.04
+0.05
+0.12
+tdyn (103 yr)
+1.07
+2.34
+11.87
+11.24
+2.03
+2.31
+4.33
+˙Mout (10−4 M⊙ yr−1)
+5.36
+1.62
+7.84
+3.39
+5.38
+12.67
+6.43
+a: All the values except lflow have been corrected for inclination.
+b: No SiO red lobe is detected for outflow o3c.
+Table 3 lists the derived outflow parameters with the correction of inclination.
+Here we use a
+single excitation temperatures for all the outflows. In fact, the excitation temperature may be very
+
+11
+different in different parts of outflow lobes (e.g., Green et al. 2011). We test the different excitation
+temperature in a range of 15-50 K and find that it would cause a maximum of ∼ 20% difference to
+our estimated parameters, which indicates the variations of excitation temperature only have a small
+effect on results. To check the validity of optically thin assumption, we derive the optical depth of
+SiO line using the RADEX4 Non-LTE molecular radiative transfer online tool. Because the profile
+of SiO is not gaussian, we use the Moment-2 value of each outflow lobe as velocity dispersion. The
+regions of outflow lobes are away from the center of cores, the number density of the H2 gas would
+be much smaller than the average number density of each core, which is taken to be 104cm−2. We
+use our derived SiO column densities to calculate the optical depth of each lobe. The derived optical
+depths are smaller than 1 (range from 0.06 to 0.79), except for o3a, which indicates that the optically
+thin assumption of SiO is relatively reasonable. For outflow o3a, the two lobes are optically thick,
+resulting in underestimations for the derived parameters.
+The outflow mass-loss rates in Table 3 are in orders of 10−4 M⊙ yr−1, comparable to the outflow
+mass-loss rates observed in several high-mass star forming regions (e.g., Zhang et al. 2005; Wang
+et al. 2014; Liu et al. 2017), while they are more than three order magnitudes higher than those
+in low-mass star formation regions (e.g., Phan-Bao et al. 2014; Santamar´ıa-Miranda et al. 2020).
+Assuming outflows are powered by accretion disks, we can infer the mass accretion rates according
+to the outflow force derived from SiO (5-4) (Bontemps et al. 1996):
+˙Macc =
+1
+fent
+˙Macc
+˙Mw
+1
+Vw
+Pout
+tdyn
+(10)
+where fent is the entrainment effiiciency relating the SiO outflow source to the momentum flux of the
+wind at its source. The value of fent is typically in range of [0.1, 0.25] and we take it as 0.25 (Liu
+et al. 2017).
+˙Mw
+˙Macc is the ratio of the wind/jet mass-loss rate to the mass accretion rate and the typical
+value is ∼ 0.1 based on magneto-hydrodynamic models (e.g., Konigl & Pudritz 2000; Cabrit 2009).
+After assuming a typical jet/wind velocity of Vw ∼ 500 km s−1, we can estimate the total accretion
+rates of o2a, o3a, o3b, o3c are about 5.7 × 10−4, 6.0 × 10−4, 7.2 × 10−4, 8.9 × 10−4 M⊙ yr−1 and the
+uncertainties of the estimated mass accretion/outflow rates are mainly caused by the uncertainties
+of the parameters discussed above. Compared to previous studies, the mass accretion rates here are
+comparable to some massive star formation models (e.g., McKee & Tan 2003; Wang et al. 2010) and
+some other outflow studies in high-mass star forming regions (e.g., Zhang et al. 2005; Qiu et al. 2009;
+Liu et al. 2017; Lu et al. 2018).
+The uncertainties of derived outflow parameters can come from many aspects such as the SiO
+abundance, outflow inclination angle, error in measurement, optically thin assumption, and adopted
+excitation temperature. Here we only consider the uncertainties caused by three main aspects. First,
+the typical uncertainty of SiO abundance is considered to be a factor of 10 (∼ 1 dex), and the
+maximum value can be up to two order of magnitudes. Second, considering an angle range from
+15 degrees to 75 degrees, the uncertainty caused by inclination angle will range from 2 to 5 due
+to the different formula forms about angles (∼ 0.3-0.7 dex). Third, the error in measurement is
+considered to be 50% (∼ 0.2 dex), including uncertainties of flux and distance. Taking all these
+things into account, we estimate an uncertainty of 1.5-1.9 dex (a factor of 30-80) in the derived
+4 http://var.sron.nl/radex/radex.php
+
+12
+Jiao, Wang et al.
+outflow and accretion parameters except for the dynamical timescale, and note that the uncertainty
+will be even larger in some regions. Because of the large uncertainties, we will not discuss these
+results further. The uncertainty of dynamical timescale only comes from the inclination angle and
+the error in measurement. We do not detect SiO outflow around Core 1 and the dynamical timescale
+of Core 2 and Core 3 is about 103 and 104 years. From the calculation of dynamical timescale, we
+derive an evolutionary picture from Core 1 to Core 3. Here we perform a Monte Carlo simulation
+to test the credibility of this conclusion. Assuming all orientations are equally favorable between 15
+degrees to 75 degrees and adding an additional 50% error of measurement, the probability that this
+conclusion still holds is ∼ 97%. So the evolutionary sequence from Core 1 to Core 3 derived from
+dynamical timescale is relatively credible after considering the uncertainties.
+3.4. Dense Core Structure
+Using the combined ALMA 12m+7m continuum image, we can measure the intensity profiles of
+each core at 1.3 mm wavelength. We calculated the averaged intensity profiles in annuli with a width
+of 0.4′′ as a function of the projected distance to the core center (from 0.4′′ to 4′′). Because the
+maximum recoverable scale for 7 m data is 36′′, greatly larger than the core size, we can ignore the
+effect of missing flux. We smooth the continuum image to a circular beam of 1.72′′ ×1.72′′ in advance
+to eliminate the effect of the elliptical beam shape. In order to estimate the density profile and derive
+the dynamical properties of each core, we assume that the density and temperature profiles both have
+power-law function forms: ρ = ρ0 (r/r0)−p and T = T0 (r/r0)−q within a maximum core radius rmax.
+Under optically thin assumption, and Rayleigh–Jeans approximation, the intensity profiles can be
+derived analytically following the relation: Iν(r) ∝ r1−(p+q) (e.g., Beltr´an et al. 2002). The fitting
+results are listed in Table 4.
+Because the optically thin assumptions may not be accurate for compact cores, we carry out
+radiative transfer analysis using RADMC-3D (Dullemond et al. 2012) and compare the results with
+the observations to give a more accurate estimation of dense core structures and virial states. Here
+we briefly describe our models. We assume that both of the density and temperature profile have a
+power-law function form within a maximum core radius of 0.1 pc. If the core is internally heated, the
+temperature profile index q equals to 0.33 (Scoville & Kwan 1976). However, for the edge part in our
+model, the external heating effect from the nearby HII regions can play an important role and we
+set the lowest dust temperature as 10 K in our models. We use the temperature derived in Section
+4.1 to estimate temperature structures. For Core 1, we set T0 = 16.64 K and q = 0 because there is
+no clear evidence of internal heating. For Core 2 and 3 with clear internal heating evidence, we set
+q = 0.33 and T0 equals to 79.5 and 58.8 K, respectively. There is no necessity to consider the index
+of dust opacity law because we only have dust continuum at a single wavelength. We assume dust
+opacities with the value of κ = 0.90 cm2 g−1 at 1.3 mm for 106 cm−3 and range in different densities
+based on the OH5 models in Ossenkopf & Henning (1994).
+In summary, we need to fit two free parameters, the density in the reference radius r0 (ρ0) and the
+density profile index (p). The value of r0 is arbitrary and we set r0 = 2000 AU (∼ 0.01 pc) in our
+calculations.
+The fitting procedure is similar to some previous studies (S´anchez-Monge et al. 2013; Palau et al.
+2014). We make the sampling in two-dimensional parameter space and calculate the residuals in
+
+13
+Figure 5. Best-fit intensity profiles of three cores. The blue line is the best-fit model and the blue points are
+the observational results. The grey dashed line represents the response of the beam and the black horizontal
+dotted line marks the 3σ noise levels.
+
+Core 1 best-fit mode
+102
+Intensity(Mjy/sr)
+101
+10-2
+10-1
+r(pc)Core 2 best-fit mode
+102.
+Intensity (Mjy/sr)
+101
+10-2
+10-1
+r(pc)Core 3 best-fit mode
+102
+Intensity (Mjy/sr)
+101
+10-2
+10-1
+r(pc)14
+Jiao, Wang et al.
+Table 4. Best-fit Parameters of Dense Core Structures
+Core
+q
+ρ0a
+pa
+χ2
+min
+χr
+p1b
+(g cm−3)
+(RADMC)
+(analytical)
+1
+0
+(1.7 ± 0.5) × 10−19
+1.36 ± 0.22
+1.18
+0.44
+1.67 ± 0.08
+2
+0.33
+(0.9 ± 0.2) × 10−19
+1.70 ± 0.24
+1.10
+0.43
+1.75 ± 0.09
+3
+0.33
+(1.0 ± 0.2) × 10−19
+1.48 ± 0.18
+2.48
+0.64
+1.63 ± 0.10
+a: free-parameters fitted in RADMC-3D.
+b: density profile index derived from analytically relation: Iν(r) ∝ r1−(p1+q).
+every step:
+χ2 ≡
+n
+�
+i=1
+�yobs
+i
+− y mod
+i
+(ρ0, p)
+σi
+�2
+(11)
+The initial value is set to be p = 1.5 ± 1.5, ρ0 = (1.0 ± 1.0) × 10−18 g cm−3. We run 1000 samples
+in one loop to find the best-fit values and reduce the step length by 20% in the next loop. The
+final best-fit parameters are selected after ten loops which consist of 10000 models. For the fitting
+with two free parameters, the uncertainty of each parameter can be estimated within the limit:
+∆χ2 = χ2 − χ2
+min < 2.3. We show the best-fit results in Figure 5 and list the best-fit parameters in
+Table 4. Comparing the fitting results with analytical solution, we find that the analytical solution
+would overestimate the density profile index by 3% − 20%. Considering the possible CO outflow in
+Core 1, we also test the model that Core 1 is in protostellar phase. We set q=0.33 and maintain other
+parameters, and the derived density profile index and analytical results are 0.95 ± 0.26 and 1.34 ±
+0.08. The density profile index is also underestimated and the proportion of underestimation reaches
+∼ 40%. The reason for the systematic difference is that the optical depth is assumed to be constant
+in the analytical solution. In fact, the optical depth is a function of the radius, decreasing as the
+radius increases. The density profile index ranges in 1.36−1.70, consistent with previous results of
+massive cores in high-mass star forming regions on 103 − 105 au scales (e.g., Wang et al. 2011; Butler
+& Tan 2012; Li et al. 2019a; Gieser et al. 2021).
+3.5. Dynamical States of Cores
+Studies have shown that the abundance of N2D+ remains high in the very early evolutionary stage
+of star formation (e.g., Crapsi et al. 2005; Kong et al. 2015) and N2D+ is a good tracer to probe the
+dynamical states of prestellar/protostellar cores (e.g., Kong et al. 2017). To derive the dynamical
+states and virial parameters of continuum cores, we need to fit N2D+ spectra within three cores. We
+use Pyspeckit (Ginsburg & Mirocha 2011) to fit hyperfine structures of N2D+, deriving the centroid
+velocity and velocity dispersion. Under the optically thin assumption, the upper limit of optical
+depth is set to be 0.5 (the rationality of optically thin assumption can be seen in Section 3.6 for
+RADEX analysis).
+We detect N2D+ in all three cores and the N2D+ spectra of three cores are
+shown in Figure 6. Core 2 and Core 3 have a single velocity component and Core 1 has two velocity
+components higher than 5σ. We make N2D+ channel maps in Appendix C to visualize the data. As
+the Figure 13 shows, all the velocity components are associated with the central cores and the two
+velocity components in Core 1 are not spatially resolved. For Core 1 with two velocity components,
+we estimate the gas mass of each velocity component assuming the continuum flux is proportional
+
+15
+Figure 6. Core-averaged fitting results of N2D+. The red line is the best-fit results and the green line is
+the fitting residual shifted by 0.5 K. The texts in the upper right are the best-fit parameters of hyperfine
+structures.
+
+Core 2 N2D+ Spectrum
+2.0
+Tex(0)=
+6.85 ±
+0.38
+0.5
+=(0)1
+v(0)=
+11.448 ±
+0.039
+1.5
+g(0)=
+0.28 ±
+0.04
+1.0
+0.5
+0.0
+-0.5
+-1.0
+5
+10
+15
+0
+20
+25
+Velocity (km s-1)Core 3 N2D+ Spectrum
+2.0
+7.23 ±
+Tex(0)=
+0.17
+t(0)=
+0.5
+v(0)=
+12.235 ±
+0.023
+1.5
+0.377 ±
+g(0)=
+0.023
+1.0
+0.5
+0.0
+-0.5
+-1.0
+10
+0
+5
+15
+20
+25
+Velocity (km s-1)Core 1 N2D+ Spectrum
+2.0
+Tex(0)=
+8.95 ±
+0.37
+0.5
+t(0)=
+v(0)=
+12.643 ±
+0.026
+1.5
+g(0)=
+0.235 ±
+0.024
+Tex(1)=
+15
+t(1)=
+0.060 ±
+0.008
+1.0
+v(1)=
+11.133 ±
+0.094
+g(1)=
+0.58 ±
+0.11
+0.5
+0.0
+-0.5
+-1.0
+10
+15
+0
+5
+20
+25
+Velocity (km s-1)16
+Jiao, Wang et al.
+Table 5. Core Dynamical Parameters
+Core
+Component
+v
+σobs
+σtot
+Mvir
+Mgas
+αvir
+Ms
+(km s−1)
+(km s−1)
+(km s−1)
+(M⊙)
+(M⊙)
+1
+1
+11.1
+0.58±0.11
+0.61±0.11
+8.3±2.9
+4.7±2.2
+1.8±1.0
+4.0±0.8
+2
+12.6
+0.24±0.02
+0.30±0.02
+2.0±0.3
+6.8±3.1
+0.3±0.1
+2.2±0.1
+2
+1
+11.4
+0.28±0.04
+0.33±0.04
+1.5±0.4
+14.0±5.7
+0.1±0.05
+1.7±0.3
+3
+1
+12.2
+0.38±0.02
+0.42±0.02
+3.4±0.5
+17.2±7.1
+0.2±0.1
+2.5±0.1
+to the velocity-integrated intensity of the velocity component. Then we can derive the virial mass of
+each core (see details in Bertoldi & McKee 1992; Li et al. 2013):
+Mvir = 5
+αβ
+σ2
+tot reff
+G
+(12)
+where parameter α = (1 − b/3)/(1 − 2b/5) is the correction to virial estimates for a power-law
+density profile ρ ∝ r−b (MacLaren et al. 1988), β = arcsin e/e is the geometry factor determined by
+eccentricity, reff is the effective radius of each core, σtot is the total velocity dispersion and can be
+derived as:
+σtot =
+��
+σ2
+obs − ∆2
+ch/(2
+√
+2 ln 2)2 − σ2
+th,N2D+
+�
++ σ2
+th,µmH
+(13)
+where σth,µmH = cs =
+�
+kBT
+µmH. Then we can derive the virial parameter αvir = Mvir/Mgas of each
+velocity component in compact sources. The uncertainties of dynamical parameters mainly come
+from three aspects: uncertainties of effective radius, uncertainties of derived velocity dispersion, and
+uncertainties of derived density profile index. The uncertainties of gas mass can be derived in Section
+3.1. Considering the possible difference of N2D+ abundances in different velocity components of Core
+1, we add an additional 20% uncertainty in gas mass. As can be seen in Table 5, for the two cores with
+SiO outflow activities (Core 2 and Core 3), αvir is smaller than 0.5, which means that the two cores
+are gravitationally unstable. For the core at the earliest evolutionary stage (Core 1), the component
+with high centroid velocity is likely to undergo gravitational collapse and the component with low
+centroid velocity is in a critical state bound by gravity. If we consider the Core 1 at protostellar
+stage and apply b=0.95±0.26 into calculation, the derived virial parameters will be 1.9±1.1 and
+0.3±0.1 for component 1 and component 2, respectively, which would not affect our conclusions.
+The different dynamical states may indicate unresolved structures. In addition, we also calculate the
+Mach number using Ms =
+√
+3σnt,N2D+/cs. All the Mach numbers are higher than 1, which indicates
+general supersonic turbulence in this star-forming region.
+3.6. Deuterium Fraction
+Previous studies found that the deuterium fraction of N2H+ decreases with time after protostellar
+stages (e.g., Fontani et al. 2011; Gerner et al. 2015). In this section we calculate the deuterium
+fraction of N2H+ in three cores using SMA data.
+The SMA data covers both N2H+ and N2D+
+lines, which provides good opportunities to compare our results with previous studies. Because the
+cores are barely resolved in these lines, we extract the spectra of N2H+ and N2D+ at the center
+
+17
+Figure 7. Left: Moment-0 maps of the N2D+ and N2H+. The integrated velocity ranges from 8 km s−1
+to 15 km s−1. The white ellipse in the bottom left marks the SMA synthesized beam. The black crosses
+represent the position of the core center identified in ALMA data. Right: The spectra of the N2D+ and
+N2H+ extracted from the pixel where the core center is.
+Table 6. Deuterium Fraction of N2H+
+Core
+σT (N2D+)
+NN2D+
+σT (N2H+)
+NN2H+
+[N2D+/N2H+]
+(K)
+(1011 cm−2)
+(K)
+(1011 cm−2)
+1
+0.036
+5.7 (1.3)
+0.102
+6.1 (3.5)
+0.93 (0.62)
+2
+0.032
+4.8 (1.0)
+0.088
+24.9 (3.1)
+0.19 (0.05)
+3
+0.032
+7.0 (1.1)
+0.100
+46.0 (3.5)
+0.15 (0.03)
+of cores which are identified in Section 3.1. Figure 7 shows the integrated emission maps and the
+extracted spectra of three cores. We calculate the N2H+ and N2D+ column densities using equation
+4 under the same assumptions with the excitation temperature equals to 15 K. In this calculation we
+don’t distinguish the two velocity components in Core 1 as mentioned in Section 3.5. We also use the
+RADEX Non-LTE molecular radiative transfer tool to check the validity of optically thin assumption.
+
+N2D+(3-2)
+0.8
+-20°14'50"
+0.6
+-
+Core
+15'00"
+0.4
+(2000)
+Core 3
+Dec
+Core 2
+0.2
+K
+10
+0.0
+20=
+0.2
+0.4
+18^09m225
+2i5
+205
+RA (J2000)
+N2H+ (3 - 2)
+6
+-20°14'50*
++
+Core1
+15'00"
+(J2000)
+2
+Core3
+Dec
+Core 2
+10"
+0
+-2
+20
+18°09m22s
+2is
+205
+RA (J2000)Core 1
+1.4
+N2D +
+N2H+
+1.2
+1.0
+0.8
+0.6
+0.4
+0.2
+0.0
+-0.2
+Core 2
+1.4
+N,D +
+N2H+
+1.2
+1.0
+0.8
+0.6
+0.4
+0.2
+0.0
+-0.2
+N,D +
+N2H+18
+Jiao, Wang et al.
+The abundance of N2H+ is much higher than N2D+, using the derived column densities of N2H+,
+we find the optical depth of each hyperfine component ranges from 10−4 to 5 × 10−2, indicating the
+optically thin assumption is reasonable for all three cores. To estimate the uncertainties of column
+densities, we use Monte Carlo method by adding to each pixel a gaussian noise centered at 0 K, with
+a standard deviation of σT. Note that we mask the data points in Core 1 where Tb < 0 K because
+of the effect of side lobes. We repeat the calculations for 1000 times and take the standard deviation
+as the uncertainties of column densities. We list the final results in Table 6. Although a low signal-
+to-noise ratio of N2H+ cause an unreliable estimate of uncertainty for Core 1, the decreasing trend
+of deuterium fraction is clearly evident in the spectra. This indicates an early to late evolutionary
+sequence from Core 1 to Core 3.
+4. DISCUSSION
+4.1. Potential Bias from Temperature Estimation
+In our analysis, we apply a uniform temperature to each core using the dust temperature of G10.21.
+However, we find SiO outflow activities in Core 2 and Core 3, which indicates that the three cores in
+G10.21 might be at different evolutionary stages. It is a crude assumption to consider a single dust
+temperature for all the cores and here we would like to give a correction to the temperature. Besides
+NH3, H2CO lines can also be used as a thermometer in dense molecular clouds (Mangum & Wootten
+1993). The H2CO lines around 218 GHz are easily measured and widely used in high-resolution
+interferometric observations (e.g., Lu et al. 2017; Beuther et al. 2021). Here we use the eXtended
+CASA Line Analysis Software Suite (XCLASS, M¨oller et al. 2017) to fit the rotational temperature
+of para − H2CO lines. We fit the average spectra of each core and use the Trot (H2CO) to replace the
+dust temperature. The line fitting is shown in Figure 8. There is no clear detection of para − H2CO
+lines in Core 1, which indicates that the dust temperature around Core 1 is relatively low. The
+dust temperature applied in Core 1 is reasonable and we only apply the temperature correction in
+Core 2 and Core 3. However, the para − H2CO lines are easily affected by outflow activities (e.g.,
+G´omez-Ruiz et al. 2013) and the outflow lobes are very close to the core center, which suggests
+that we may overestimate the dust temperature using the above correction. Here we also apply a
+temperature of 40 K (a typical temperature for protostars) towards the two cores and the results
+after temperature correction are listed in Table 2. If we consider Core 1 at the protostellar stage
+and apply the temperature of 40 K to Core 1, the mass and density of Core 1 will be 3.9 M⊙ and
+8.7 × 105 cm−3, respectively, making the mean number density of Core 1 several times smaller than
+Core 2 and Core 3. The uncertainties of derived parameters are similar to the previous discussion in
+Section 3.1.
+From Table 2 we can see that the mass of two protostars becomes relatively low after applying
+the temperature correction. Though we consider the overestimation from the fitting of para − H2CO
+lines, there are no more massive protostars in G10.21. The results may indicate that the core at the
+earliest stage contains the maximal mass, which is in contrast with the competitive accretion model
+(Bonnell et al. 2001). However, we don’t know what percentage of the gas can eventually be fed
+into the collapse of the core. The evolution path of Core 1 still needs to be further explored. The
+density of dense cores at different evolutionary stages is comparable after applying the temperature
+correction. Kong et al. (2021) investigate density change during high-mass star formation and find
+
+19
+Figure 8. Core-averaged fitting results of para − H2CO lines. The black line is the best-fit results and red
+line marks the residual. The line around 218.43 GHz is one of CH3OH lines which is not covered in this fit.
+Here we mask the residual of this line in the figure.
+
+Core 1
+Fit
+3
+Observation
+X-1K
+2
+K
+0
+-1
+218800
+218000
+218200
+218400
+218600
+219000
+219200
+Frequency (MHz)Core 2
+Trot (H2CO) = 83.0 K
+Fit
+3
+Observation
+X-1K
+2
+K
+0
+1
+218000
+218200
+218400
+218600
+218800
+219000
+219200
+Frequency (MHz)Core 3
+Trot (H2CO) = 67.7 K
+Fit
+3
+Observation
+X-1K
+2
+K
+7
+0
+-1
+218000
+218200
+218400
+218600
+218800
+219000
+219200
+Frequency (MHz)20
+Jiao, Wang et al.
+Figure 9. Left: Moment-0 maps of the three deuterated molecules after primary beam correction overlaid
+with 1.3 mm continuum map. The blue, yellow, red contours represent the emission of N2D+, DCN, DCO+,
+at levels of [3, 5, 7, 9,...]σ, where σ equal to 0.62, 0.45, 0.47 K km s−1, respectively. Right: Core-averaged
+spectra of the three deuterated molecules within the three compact cores.
+no difference when comparing the populations at different evolutionary stages, consistent with our
+results in Table 2.
+4.2. Gas Fragmentation
+Fragmentation exists at different scales from giant molecular clouds to small gas clumps. In Section
+3.1, we find clear fragmentation in G10.21 and we will discuss how this source fragments into dense
+cores that have the potential to form high-mass stars.
+If the fragmentation is dominated by thermal Jeans instability (Jeans 1902), the separation between
+the cores and the mass of cores will be comparable to the Jeans length and Jeans mass of G10.21.
+We calculate the Jeans length and Jeans mass following Wang et al. (2014):
+λJ = cs
+� π
+Gρ
+�1/2
+= 0.066 pc
+� T
+10 K
+�1/2 �
+n
+105 cm−3
+�−1/2
+(14)
+MJ = π5/2c3
+s
+6
+�
+G3ρ
+= 0.877 M⊙
+� T
+10 K
+�3/2 �
+n
+105 cm−3
+�−1/2
+(15)
+where the temperature T is the kinetic temperature derived from ammonia in Section 3.1 and density
+n is the average density of G10.21 (Yuan et al. 2017). The Jeans length and Jeans mass of G10.21
+is about 0.04 pc and 0.97 M⊙. In our sample, the initial fragmentation leads to three massive cores
+with masses from 11 to 18 M⊙ with an average separation of 0.12 pc in the plane of sky. Considering
+the projection effects, the mean separation would be even larger than 0.12 pc. The large difference
+
+0.008
+20-14'55
+Core 1
+0.006
+0
+15'D0"
+0.004
+tooozn :
+Jy/beam
+Core 3
+0.002
+05"
+N2D +
+Core 2
+0.000
+DCN
+1g*
+DCO+
+0.002
+0.004
+18*0921.0*
+20'5*
+20.0*
+RA (JZDOO)N2D +
+DCN
+DCO+
+>>>>>>>>?
+><>>>>
+20
+10
+20
+30
+40
+N2D +
+DCN
+DCO
+-20
+-10
+10
+20
+30
+40
+N2D +
+DCN
+DCO+
+>>>>>21
+Figure 10. The relation between fragment mass and nearest separation distance. The grey downwards
+triangles mark the data of G28-P1 (Wang et al. 2011). The grey upwards triangles represent the data of G30-
+C2 (Zhang & Wang 2011). The grey circles show the data of G11-P1 and G11-P6 (Wang et al. 2014). The
+blue crosses and orange crosses mark the data in our work. The orange shaded regions show the sensitivity
+and resolution limit of the our ALMA observations. The dotted line shows thermal Jeans fragmentation
+with T = 18.5 K and n = [102, 108] cm−3, and the blue shaded region corresponds to the same density
+range but with T = [10, 30] K. The solid line shows a scale-free turbulent Jeans fragmentation with effective
+temperature Teff of 175 K (total velocity dispersion σ = 0.78 km s−1) and the same density range. The green
+shaded region corresponds to the same density range but with Teff = [46, 413] K (i.e., σ = [0.4, 1.2] km s−1).
+The sizes indicate the physical scales of grey data points: the smallest are condensations (∼ 0.01 pc),
+the middle are cores(∼ 0.1 pc), and the largest are clumps(∼ 1 pc). This figure shows clearly that the
+fragmentation in G10.21 are likely dominated by turbulence over thermal pressure at core scales under the
+sensitivity of our observations.
+indicates that the fragmentation is not only controlled by gravity and thermal pressure, which is
+consistent with the conclusion derived in Zhang et al. (2021).
+
+104
+Thermal Jeans fragmentation
+Scale-free turbulent Jeans fragmentation
+G28-P1 (Wang+2011)
+G30-C2 (Zhang+2011)
+103
+G11-P1/6 (Wang+2014)
+G1o.21-Cores (this work)
+.21
+102
+G1
+of
+101
+condensation (0.01 pc)
+core (0.1 pc)
+clump (1 pc)
+tial
+100
+Spat
+MassSensitivityofG1021
+10-1
+10-2
+10-1
+100
+101
+Nearest Separation (pc)22
+Jiao, Wang et al.
+If we replace the cs by the total velocity dispersion of NH3 measured in Wienen et al. (2012)
+(σ = 0.78 km s−1), we can calculate the effective Jeans length and Jeans mass with the support of
+thermal pressure and turbulence. To investigate the role of turbulence in gas fragmentation, we use
+the similar method from Wang et al. (2014) to visualize the relation between fragment mass and
+nearest separation distance. The results are shown in Figure 10. This figure includes data points
+from previous relevant works at different spatial scales that can be compared with our measurements.
+The shaded blue region represents the thermal Jeans fragmentation domain where the adopted tem-
+perature and density are in ranges T = [10, 30] K and n = [102, 108] cm−3. The shaded green region
+represents the turbulent Jeans fragmentation domain with the same density range and effective tem-
+perature range Teff = [46, 413] K (i.e. total velocity dispersion σ = [0.4, 1.2] km s−1). From Figure
+10 we can conclude that the fragmentation in G10.21 is likely dominated by turbulence over thermal
+pressure at core scales within the sensitivity bounds of our observations, which is consistent with
+several previous works (e.g., Zhang et al. 2009; Pillai et al. 2011; Wang et al. 2011, 2014). Recent
+high-resolution observations down to the smallest accessible spatial scales find high-level fragmen-
+tations, more consistent with thermal Jeans fragmentation of dense cores (e.g., Palau et al. 2018;
+Beuther et al. 2019; Tang et al. 2021).
+We cannot exclude the possibility that these cores may
+harbor further fragmentations not resolved, especially the SiO outflow image and different velocity
+components are consistent with the possibility. Further high resolution observations are needed to
+investigate the fragmentation mechanism at smaller scales.
+4.3. Deuterated Molecules as Chimecal Clocks
+Deuterated molecules are sensitive to temperature, which can provide useful information to probe
+the initial conditions (e.g., Bacmann et al. 2003; Pillai et al. 2007; Li et al. 2021). Because of the
+different formation mechanisms, different deuterated species trace sources in different evolutionary
+stages. For example, the abundance of N2D+ will decrease after the onset of star formation (e.g.,
+Caselli et al. 2002; Fontani et al. 2011), while DCO+ and DCN are more likely to be detected in
+warm environments (Gerner et al. 2015). The combination of the three deuterated molecules can
+be treated as chemical clocks, which has been proven by recent observations (e.g., Morii et al. 2021;
+Sakai et al. 2021).
+Figure 9 shows the distribution of the three deuterated molecules overlaid with the 1.3 mm con-
+tinuum map and the spectra of the three cores. Core 1 shows strong N2D+ emission but no DCO+
+and DCN emission, which is considered at the earliest evolutionary stage in star formation. Core 2
+exhibits weak N2D+ and DCO+ emission, which indicates the core has just ignited star formation
+activities for a short period. Meanwhile, we can see clear DCN and DCO+ emission and weak N2D+
+emission within Core 3, which suggests Core 3 is at the latest evolutionary stage of star formation
+among the three cores. Here we estimate an evolutionary sequence from Core 1 to Core 3, consistent
+with the results derived from outflow activities. We don’t give a quantitive correlation between the
+ratio of deuterated molecules and the dynamical timescale due to insufficient sample size. Detailed
+studies of the relation need to be investigated in a larger sample.
+4.4. The Potential for High-mass Star Formation
+G10.21 is considered as a high-mass starless core candidate, which is at the earliest stage of high-
+mass star formation. In this section we will discuss whether high-mass stars can form in this source.
+
+23
+According to Kauffmann & Pillai (2010), the region which has the potential to form high-mass
+stars should follow the relation: m(r) ⩾ 580 M⊙(r/pc)1.33, after rescaling the dust opacities without
+the factor of 1.5 reduction (see the discussion in Dunham et al. 2011). Applying the equivalent
+radius r=0.13 pc to the equation, the derived mass threshold is 38 M⊙. The mass surface density
+is another widely used parameter to estimate the potential of high-mass star formation. Urquhart
+et al. (2013) suggest an empirical threshold for high-mass star formation of 0.05 g cm−2. The mass
+and surface density of G10.21 are estimated to be 314 M⊙ and 1.28 g cm−2, greatly exceeding the
+above thresholds, which indicates that G10.21 has enough potential to form high-mass stars.
+Since high-mass stars could form in G10.21, we can estimate the possible maximum stellar mass
+using the properties of G10.21.
+Based on the empirical relation mentioned in Larson (2003):
+�
+mmax
+M⊙
+�
+= 1.2
+�
+Mcluster
+M⊙
+�0.45
+, assuming a 30% star formation efficiency, G10.21 could form a stellar
+cluster with a total stellar mass of 94 M⊙. The derived maximum stellar mass is 9.3 M⊙. Sanhueza
+et al. (2017) suggests another relation to estimate the maximum stellar mass using the the IMF from
+Kroupa (2001):
+mmax =
+�0.3
+ϵsfe
+17.3
+Mclump
++ 1.5 × 10−3
+�−0.77
+M⊙
+(16)
+Using the same 30% star formation efficiency, a high-mass star with the mass of 9.1 M⊙ could form.
+In Section 3.1, the derived mass of identified cores ranges from 11.5-17.2 M⊙, slightly larger than the
+derived maximum stellar mass. The comparison indicates further fragmentation at smaller scales,
+which is consistent with our results (multiple outflows in Section 3.3 and velocity components in
+Section 3.5).
+Here we propose a possible evolutionary picture of G10.21. G10.21 is at a very early evolutionary
+stage of high-mass star formation due to its short dynamical timescale.
+It fragments into three
+dense cores, among them Core 3 starts the star-forming activities first and Core 1 is at the earliest
+evolutionary stage. No high-mass prestellar core is found in G10.21. Based on our results, we predict
+the three dense cores would fragment into more gas condensations at smaller scales. High-mass stars
+will eventually form in G10.21 upon the completion of gas accretion.
+5. CONCLUSION
+We study the fragmentation, core properties and chemical evolution towards a high-mass prestellar
+core candidate G10.21, using ALMA and SMA observations. Our main findings are as follows:
+(1) We found three continuum compact sources in G10.21, with masses ranging from 11 M⊙ to
+18 M⊙ at a uniform dust temperature of 16.6 K. We find a coherent evolutionary sequence from
+Core 1 to Core 3, based on line richness, outflow properties, deuterated molecules distribution, and
+deuterium fraction of N2H+. No high-mass prestellar core is found in this source. This suggests a
+dynamical star formation where cores grow in mass over time.
+(2) Several outflows are identified in SiO (5-4) and CO (2-1) lines. We derive the outflow parameters
+of lobes that are identified in both tracers, consistent with the previous work of other high-mass star
+forming regions. The dynamical timescale of Core 2 and Core 3 is roughly 103 and 104 yr using SiO
+outflows and we derive an evolution picture from Core 1 to Core 3.
+(3) We derive the core structures using radiative transfer tools and compare the density profile index
+with it derived from the typical analytical method. The results are comparable, while the analytical
+method may overestimate the index by 3% − 20%. We also derive the virial parameters using the
+
+24
+Jiao, Wang et al.
+above index, finding different virial status of different cores.
+In addition, all the Mach numbers
+are higher than 2, suggesting general supersonic turbulence in G10.21. Turbulence is considered to
+play important roles in fragmentation at core scales in G10.21 within the sensitivity bounds of our
+observations.
+(4) We derive the deuterium fraction of N2H+ using SMA data. The deuterium fraction of N2H+
+decreases with the evolution of cores, which is consistent with previous works. We also derive similar
+conclusions through the spatial distributions of three deuterated molecules observed by ALMA. The
+combination of three deuterated molecules and outflow activities can be treated as chemical clocks,
+which need to be investigated quantitively in a larger sample in the future.
+ACKNOWLEDGEMENTS
+We are grateful to an anonymous referee for the constructive comments that helped us improve this
+paper. We acknowledge support from the China Manned Space Project (CMS-CSST-2021-A09, CMS-
+CSST-2021-B06), the National Key Research and Development Program of China (2017YFA0402702,
+2019YFA0405100), the National Science Foundation of China (11973013, 11721303), and the High-
+Performance Computing Platform of Peking University.
+TGSP gratefully acknowledges support
+by the National Science Foundation under grant No.
+AST-2009842.
+TB acknowledges support
+from S. N. Bose National Centre for Basic Sciences, under the Department of Science and Tech-
+nology, Government of India.
+This research has made use of the NASA/IPAC Infrared Science
+Archive, which is funded by the National Aeronautics and Space Administration and operated by
+the California Institute of Technology.
+This paper also makes use of the following ALMA data:
+ADS/JAO.ALMA#2016.1.01346.S. ALMA is a partnership of ESO (representing its member states),
+NSF (USA) and NINS (Japan), together with NRC (Canada), MOST and ASIAA (Taiwan), and
+KASI (Republic of Korea), in cooperation with the Republic of Chile. The Joint ALMA Observatory
+is operated by ESO, AUI/NRAO and NAOJ.
+Facilities: ALMA, SMA, Spitzer, Herschel, APEX
+APPENDIX
+A. SPECTRA EXTRACTED FROM CORES
+Figure 11 shows the spectra extracted from identified cores. The typical warm gas tracers such as
+CH3OH and H2CO are detected in Core 2 and Core 3, indicating their protostellar properties. This
+deduction is consistent with the observations of outflows. No organic molecule emission is detected
+in Core 1, suggesting it at a very early evolutionary stage.
+Detailed discussion about the three
+deuterated molecules is described in Section 4.3. We find a clear trend in line richness from Core 1
+to Core 3, changing from poor to abundant. Chemical difference is evident in the spectra of three
+cores, related to their different chemical ages.
+B. CO OUTFLOW IDENTIFICATION
+The CO maps show complicated emission structures, which is difficult to identify outflow activities.
+We identify the CO outflows through carefully visual inspection. In order to detect the possible weak
+outflow lobes, we mask the strong environmental emission and check the channel maps around each
+core.
+Each identified lobe need to be detected over twenty channels (≥ 7 km s−1) with enough
+
+25
+1.0
+0.5
+0.0
+0.5
+1.0
+1.5
+2.0
+2.5
+3.0
+ALMA Core1
+C18O
+CO
+N2D+
+Prestellar?
+H2CO
+1.0
+0.5
+0.0
+0.5
+1.0
+1.5
+2.0
+2.5
+3.0
+C18O
+CO
+N2D+
+ALMA Core2
+Protostellar
+DCN
+SiO
+CH3OH
+H2CO
+H2CO
+H2CO
+Tb (K)
+216.0
+216.5
+217.0
+217.5
+1.0
+0.5
+0.0
+0.5
+1.0
+1.5
+2.0
+2.5
+3.0
+218.0
+218.5
+219.0
+219.5
+230.5
+231.0
+231.5
+232.0
+232.0
+232.5
+233.0
+233.5
+Frequency (GHz)
+C18O
+CO
+N2D+
+ALMA Core3
+Protostellar
+DCN
+SiO
+CH3OH
+H2CO
+H2CO
+H2CO
+DCO+
+Figure 11. Spectra extracted from identified cores. The gaps separate the four ALMA spectral windows.
+Molecules with clear detection are labeled in the figure.
+emission (≥ 10 K km s−1). For those lobes whose driving source is difficult to estimate, we judge
+them by the corresponding bipolar features. Besides the lobes that satisfy the criteria, we also find
+a weak blue lobe around Core 1 (o1a). Figure 12 shows the CO channel maps from -15 km s−1 to
+30 km s−1. Though the velocity range of this lobe is smaller than 10 km s−1, we still consider it a
+possible outflow lobe. Meanwhile, we can’t exclude the possibility of the effect of side lobe or the
+extension of the blue lobe from o3a. In summary, this possible outflow association makes the nature
+
+26
+Jiao, Wang et al.
+Core 1
+Core 2
+Core 3
+18h09m21s
+20s
+-20°14'50"
+55"
+15'00"
+05"
+10"
+15"
+RA (ICRS)
+Dec (ICRS)
+5
+10
+15
+20
+25
+K km s
+1
+Figure 12. Channel maps of CO (2-1) after primary beam correction. The magenta contours show the
+integrated CO emission at levels of [6, 12, 24, 48, 96]σ, where σ equals to 0.83 K km s−1. The black cross
+symbols represent the peak positions of compact cores. The left-bottom blue ellipse represents the beam
+size.
+of Core 1 unclear since it could be a prestellar core or a protostellar core driving an outflow at an
+earlier phase than Core 2 and 3.
+
+27
+Core 1
+Core 2
+Core 3
+18h09m21s
+20s
+-20°14'50"
+55"
+15'00"
+05"
+10"
+15"
+RA (ICRS)
+Dec (ICRS)
+0.0
+0.4
+0.8
+1.2
+K km s
+1
+Figure 13. Channel maps of N2D+ (3-2) after primary beam correction. The magenta contours show the
+N2D+ emission at levels of [3, 6, 9, 12, 15]σ, where σ equals to 0.15 K km s−1. The black cross symbols
+represent the peak positions of compact cores. The left-bottom blue ellipse represents the beam size.
+C. N2D+ CHANNEL MAP
+As we observe multiple velocity components of N2D+ in Core 1, we make a N2D+ channel map
+to see whether the different velocity components are spatially resolved. Figure 13 shows the N2D+
+
+28
+Jiao, Wang et al.
+channel maps from 8 km s−1 to 16 km s−1. All the velocity components are associated with the core.
+The two velocity components in Core 1 are not spatially resolved.
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diff --git a/hNA0T4oBgHgl3EQfH__c/content/tmp_files/load_file.txt b/hNA0T4oBgHgl3EQfH__c/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..d58f5b53acecbf2a22f2d4f242d43ac2775cf4b5
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf,len=2000
+page_content='Draft version January 6, 2023  Typeset using LATEX preprint style in AASTeX63  Fragmentation of the High-mass “Starless” Core G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31: a Coherent  Evolutionary Picture for Star Formation  Wenyu Jiao,1, 2 Ke Wang,1 Thushara G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Pillai,3 Tapas Baug,4 Siju Zhang,1 and  Fengwei Xu1, 2  1Kavli Institute for Astronomy and Astrophysics, Peking University, Haidian District, Beijing 100871, People’s  Republic of China  2Department of Astronomy, School of Physics, Peking University, Beijing, 100871, People’s Republic of China  3Institute for Astrophysical Research, Boston University, 725 Commonwealth Avenue, Boston MA, 02215, USA  4S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Bose National Centre for Basic Sciences, Block-JD, Sector-III, Salt Lake City, Kolkata 700106, India  ABSTRACT  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31 is a 70 µm-dark high-mass starless core (M > 300 M⊙ within r < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15  pc) identified in Spitzer, Herschel, and APEX continuum surveys, and is believed to  harbor the initial stages of high-mass star formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We present ALMA and SMA  observations to resolve the internal structure of this promising high-mass starless core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Sensitive high-resolution ALMA 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm dust continuum emission reveals three cores  of mass ranging 11-18 M⊙, characterized by a turbulent fragmentation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core 1, 2, and  3 represent a coherent evolution at three different evolutionary stages, characterized  by outflows (CO, SiO), gas temperature (H2CO), and deuteration (N2D+/N2H+).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We  confirm the potential to form high-mass stars in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 and explore the evolution path  of high-mass star formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Yet, no high-mass prestellar core is present in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  This suggests a dynamical star formation where cores grow in mass over time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Keywords: massive stars (732);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Infrared dark clouds (787);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' protostars (1302);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' star for-  mation (1569)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' INTRODUCTION  High-mass stars play essential roles in the evolution of their host galaxy via their radiation, stellar  wind and supernovae events.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' However, compared with their low-mass counterparts, the formation  mechanism of high-mass stars is poorly understood (Tan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2014;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Motte et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2018).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  There are two mainstream models describing the forming process of high-mass stars: the monolithic  collapse model (McKee & Tan 2003) and the competitive accretion model (Bonnell et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2001).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In  the monolithic collapse model, the final stellar mass is pre-assembled in a single high-mass turbulent  core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Turbulence can effectively resist self-gravity until the accretion mass is large enough.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' So this  model requires the existence of high-mass starless cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In the competitive accretion model, high-  mass stars begin as low-mass cores (∼ 1 M⊙) and most of the stellar mass comes from the subsequent  Corresponding author: Ke Wang  kwang.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='astro@pku.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='cn  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='02070v1  [astro-ph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='GA]  5 Jan 2023  2  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  accretion process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Different from Bondi-Hoyle-Lyttleton-like core accretion model, recent studies also  propose some new accretion mechanisms such as gravitationally driven cloud inflow (Smith et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2009;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Hartmann et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2012) or supersonic turbulence driven inflow (Padoan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' However, both  the mechanisms are yet to get enough observational evidence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  In order to distinguish the different forming processes of high-mass stars, it is important to probe  the initial conditions towards the birthplace of high-mass star forming regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Infrared-dark clouds  (IRDCs), often considered as the cradle of massive stars, provide ideal laboratories to study the  formation of high-mass stars (Bergin & Tafalla 2007).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In recent years, many high-resolution and  high-sensitivity observations have revealed the physical properties of the cores embedded in IRDCs,  suggesting that most of the clumps in IRDCs have left the starless stage and begun star formation  activities (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
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+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Blind surveys of continuum emission at far-infrared and (sub)millimeter wavelengths towards the  Galactic plane reveal the dense structures at different evolutionary stages (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Schuller et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2009;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Molinari et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2010;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Aguirre et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Eden et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017), offering good data sets for us to search for  the cradle of high-mass star forming regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017) have selected 463 high-mass starless  clump candidates based on The APEX Telescope Large Area Survey of the Galaxy (ATLASGAL)  catalog (Schuller et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2009).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Compared with other high-mass starless clump catalogs (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Tacken-  berg et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2012;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Traficante et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Svoboda et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2016), this catalog has the largest sky coverage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Besides the commonly adopted infrared-dark criteria, this catalog also ruled out sources associated  with reported star-forming indicators and performed extra visual checks on each source, which made  it the most reliable high-mass starless clump candidate catalog.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Detailed studies towards this sample  can help us reveal the initial conditions of high-mass star forming regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31  Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017) found twenty high-mass starless core candidates with an equivalent radius smaller  than 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15 pc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31 (hereafter G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21) is the second most massive source in the sample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Figure  1 shows the infrared emission of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 at different wavelengths.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' This source is dark at near-infrared,  mid-infrared, far-infrared up to 70 µm, and transitions to be bright at longer wavelengths (250/870  µm bright).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Located at a distance of 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 kpc, this high-mass prestellar core candidate contains 314  M⊙ gas within an equivalent radius of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='13 pc (Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The luminosity of the target is  667 L⊙, leading to a relatively low luminosity-to-mass ratio (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='13 L⊙/M⊙, Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  deuterium fraction of NH3 in this source is higher than 30%, suggesting it is at a very young age  (Pillai et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2007).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The dust temperature of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 is 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 K under 36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′ resolution (Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2017) and the kinetic temperature derived from NH3 is 18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 K under 40′′ resolution (Wienen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2012).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Because of its small size, low temperature, low luminosity-to-mass ratio, high mass and high  deuterium fraction, this source is an ideal object to study the initial conditions of high-mass star  formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In addition, it is located at the edge of the HII region G010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='232-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='301 (Anderson et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2011), which may suffer strong environmental feedback.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2021) compared four pairs of  high-mass starless clumps (near or far from HII regions) and found that this source is more likely to  be affected by the surrounding HII regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Hence, exploring the initial star formation processes of  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 is of great interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The paper is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We describe the observations in Section 2 and show the main  results in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In Section 4, we discuss potential bias from temperature correction and the gas  3  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Overview of the high-mass starless core G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Four panels show images at different wavelengths  adapted from Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (a) Three color image with emission at 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5, and 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 µm rendered in  red, green, and blue, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (b) Spitzer 24 µm emission.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (c) Herschel 70 µm emission.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (d) APEX  870 µm emission (red contours) with levels of [0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5, 4, 7] Jy/beam overlaid on  Herschel 250 µm map (color).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The white cross marks the peak position of 870 µm source, and the white  ellipse describes the source size based on the major and minor half-intensity axes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  fragmentation mechanism in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We also discuss the chemical evolution in star formation to  investigate the possibility of chemical clocks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In addition, we study the potential to form high-mass  stars and describe a simple possible evolutionary picture of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Finally, we give the summary of  this work in Section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' OBSERVATIONS AND DATA REDUCTION  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' ALMA Band 6 Observations  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 was observed with ALMA in Band 6, as part of the Cold Cores with ALMA (CoCoA) survey  (Project ID: 2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='01346.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='S, PI: Thushara G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Pillai).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In this work, we combine the data of the 12  m main array and the 7m Atacama Compact Array (ACA).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The observations had four wide spectral  windows with a bandwidth of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='875 GHz for 12 m array and 2 GHz for 7 m array centered on 216.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='89,  218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='76, 231.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12, 232.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='89 GHz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The spectral windows have a uniform channel width of 244.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='14 kHz (∼  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='32 km s−1 at 230 GHz).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The phase reference center was R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (J2000) = 18:09:20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 and Decl.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (J2000)  = -20:15:04.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Quasars J1832-2039 and J1924-2914 were used for phase and bandpass calibration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  For the 12 m array observations, the source was observed on March 31, 2017 and May 14, 2018.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  maximum recoverable scale was 13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7′′ and the primary beam size was 25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9′′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The integration time  was approximately 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 minutes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Titan was used for flux calibration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For the 7 m array observations,  the source was observed in July-September, 2017.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The maximum recoverable scale was 36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′ and the  primary beam size was 44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The integration time was approximately 9 minutes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' J1733-1304 was  used for flux calibration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Data reduction was performed using CASA software package version 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 (McMullin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2007).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  For continuum data, we use the split task to obtain line-free channels in each spectral window.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The visibility data of 12 m array and 7 m array from the four spectral windows were combined in  CASA using concat task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The combined 12 + 7 m continuum visibility data was cleaned using tclean  task, with a Briggs’s robust weighting of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 and a cell size of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3′′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The synthesized beam size is  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7′′ × 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0′′ (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='03 pc × 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='02 pc at 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 kpc distance), with a position angle of −76◦.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The RMS noise of  Myr sr-1  Myr sr-1  Myr sr-1  135  393  1142  5469  9287  15769  5453  9591  16867  G010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2144-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3051  red: 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content="0 μm  (a)  (b)  24 μm  (c)  70 μm  250 μm  d  20°14'  green: 4." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 μm  blue:3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content="6 μm  (J2000)  15'  O  Dec  16'  24s  21s  18s 18h09m15s  RA (J2000)4  Jiao, Wang et al." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Summary of Spectral Line Information  Line  Transition  Rest Freq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Eu/k  Velocity Resolution  Beam Size  (GHz)  (K)  (km s−1)  (′′×′′)  DCO+  J=3 − 2  216.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='112580  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='74  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='98×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='14  SiO  J=5 − 4  217.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='104980  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='26  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='98×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='14  DCN  J=3 − 2  217.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='238530  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='85  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='98×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='14  H2CO  JKa,Kc=30,3 − 20,2  218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='222192  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='96  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='97×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12  H2CO  JKa,Kc=32,2 − 22,1  218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='475632  68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='09  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='97×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12  H2CO  JKa,Kc=32,1 − 22,0  218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='760066  68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='11  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='96×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12  CO  J=2 − 1  230.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='538000  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='60  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='32  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='83×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='07  N2D+  J=3 − 2  231.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='321828  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='20  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='32  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='82×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='07  the continuum image measured in an emission-free region is about 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 mJy/beam (∼0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15 M⊙ with a  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 K dust temperature at 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 kpc).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For spectral line, the combined 12 + 7 m line cube was cleaned  using tclean task after removing the continuum emission using uvcontsub task, with a Briggs robust  weighting of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 and a cell size of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3′′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The threshold is 2σ=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='025 Jy and the maximum number of  iteration (niter) is 10000.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Multi-scale Clean is used for CO, SiO and H2CO lines to better recover  extended emission and scales are set to be [0, 5, 15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We use auto-multithresh algorithm and the  parameters are equal to the standard value for 12m + 7m combined data in official guides1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  synthesized beam size of different lines is similar to the beam size of continuum image but has a  small difference because of the frequency offset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We summarize the spectral line information used in  our analysis in Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The typical noise level is ∼150 mK after converting the cube to brightness  temperature units.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' SMA Observations  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 was observed by SMA (project ID: 2008A-S075, PI: Thushara G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Pillai).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The observations  were performed with the LO tuned at 225.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4 GHz for N2D+ (J = 3 − 2) on August 24th, 2008 and  275.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 GHz for N2H+ (J = 3 − 2) on August 30th, 2008.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Gain calibration was performed by periodic  observations of quasars NRAO530 and J1911-201.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Uranus was used for flux calibration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 3C454.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  was used for bandpass calibration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For N2D+ observation, the on-source integration time was 98  minutes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The synthesized beam size was 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′ × 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3′′ (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='10 pc × 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05 pc), with a position angle of  23◦.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For N2H+ observation, the on-source integration time was 24 minutes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The synthesized beam  size was 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8′′ × 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2′′ (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15 pc × 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05 pc), with a position angle of −2◦.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' To compare the two SMA  cubes directly, we convolved the image to the same resolution and reprojected them into the same  grid.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The final synthesized beam was 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8′′ × 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3′′ (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15 pc × 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='06 pc), with a position angle of −2◦.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The typical noise levels were 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='10 K and 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='03 K for N2H+ and N2D+ spectra, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' RESULTS  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm Compact Continuum Sources  1 see details in https://casaguides.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='nrao.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='edu/index.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='php?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='title=Automasking Guide  5  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' ALMA 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm continuum image of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 shown in color after primary beam correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  cyan ellipse represents the deconvolved image size of the cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The white contours show emission at 870  µm from the ATLASGAL survey with the same levels in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The black contours show continuum  emission at levels of [6, 9, 12, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=']σ, where σ equals to 5 × 10−4 Jy/beam.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue ellipse in the bottom left  marks synthesized beam.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm continuum map (centered at 224.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='92 GHz) is shown in Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We use Dendrogram  algorithm2 on the continuum image without primary beam correction to identify dense cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  min value is set to be 3σ, where σ is the RMS noise of the continuum image.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The min delta is set to  be 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5σ and the min npix equals to 21 (The number of pixels within the beam area).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' To accurately  derive the position, flux density, size information of these cores, we make use of imfit function in  CASA on the 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm continuum image after primary beam correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We identified three compact  cores in this source and the detailed observed properties are listed in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' All three cores are  detected with high signal-to-noise ratios (S/N >6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2 https://dendrograms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='readthedocs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='io/en/stable/  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='010  20°14\'50"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='008  Core 1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='006  Core 3  15\'00"  Dec (ICRS)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  Jy/beam  Core  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  10"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  20"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 pc  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  18h09m22s  21s  20s  RA (ICRS)6  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core Observed Properties  Core  RA(J2000)  Dec(J2000)  Sizea  Size  PA  Speak  Score  Tdb  Mgas  nH2  (h:m:s)  (d:m:s)  (′′×′′)  (pc×pc)  (deg)  (mJy/beam)  (mJy)  (K)  (M⊙)  (cm−3)  1  18:09:20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33  20:14:55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1×3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='06×0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  106  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 × 106  2  18:09:20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='37  20:15:05.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8×2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04×0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='03  128  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 × 107  3  18:09:20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='76  20:15:00.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5×2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05×0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  13  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 × 106  T c  H2CO  (K)  1  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 × 106  2  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 × 106  3  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 × 106  T d  typical  (K)  1  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 × 106  2  40  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 × 106  3  40  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 × 106  a: Core size deconvolved from synthesized beam.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  b: Dust temperature of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 adopted from Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  c: Rotational temperature by fitting the para − H2CO lines, see more details in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  d: Typical dust temperature for protostars, see more details in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  We estimate the core mass of three identified cores based on the dust continuum flux following the  equation  Mgas = η  Fνd2  Bν(Td)κν  (1)  where Mgas is the gas mass, η = 100 is the gas-to-dust ratio, Fν is the continuum flux at frequency  ν, d is the kinetic distance of the source, Bν (Td) is the Planck function at the dust temperature, and  κν = 10 (ν/1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2 THz)β cm2 g−1 represents the dust opacity (Hildebrand 1983).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In our calculation, we  use the value of Td = 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 K derived for the whole region with 36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′ resolution in Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017)  and adopt the dust opacity index β = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' If we adopt the value of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 cm2 g−1 for dust opacity at  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm with a volume density of 106 cm−3 density from Ossenkopf & Henning (1994), the derived  gas masses from Core 1 to Core 3 will be 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4, 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6, 15.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 M⊙, leading to about 10% difference to the  final results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The number density of each core is calculated assuming the sources to be spherically symmetric  using the following equation:  nH2 =  Mgas  4  3πµmH r3  eff  (2)  where µ (µ = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='37) is the mean molecular weight per free particle, considering H2, He, and ignoring  the number of heavier elements (Kauffmann et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2008), mH is the mass of a hydrogen atom, and  reff = d  2  �  ΘmajΘmin is the equivalent radius of each core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The mean number density of cores is in  7  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Moment-0 maps of different molecular lines after primary beam correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We cut the image  at the primary beam response of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2 for CO and SiO, and 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 for other lines, leading to little differences in  field of view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The integrated velocity range is from -15 km s−1 to 30 km s−1 for CO and SiO, 4 km s−1 to  20 km s−1 for three para-H2CO lines, and from 8 km s−1 to 16 km s−1 for other lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The white contours  show continuum emission at levels of [6, 12, 24, 48]σ, where σ equals to 5×10−4 Jy/beam.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The top-left blue  ellipse in the bottom left marks synthesized beam.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Kkm s-1  Kkm s-1  Kkm s-1  30  60  06  120  150  5  10  15  20  5  10  15  20  20°14\'45"  (a) co  (b) Sio  (c) H2CO 30,3 -20,2  Dec (ICRS)  15\'00"  15\'  1809-21  20°  1809-21  20°  1809-21  20°  RA (ICRS)  RA (ICRS)  RA (ICRS)  Kkm s-i  Kkm s-i  Kkm s-1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  20°14\'45"  (d) H2CO 32,2 - 22,1  (e) H2CO 32,1- 22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 0  f)DCO  Dec (ICRS)  15\'00"  15\'  109-21-  20°  1809-21  20°  109-21-  20°  RA (ICRS)  RA (ICRS)  RA (ICRS)  Kkm s-i  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  20914\'45"  (g)DCN  (h) N2D  Dec (ICRS)  15\'00"  15"  109-21  20°  18109m21  20°  RA (ICRS)  RA (ICRS)8  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  range from 106 to 107 cm−3 as listed in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The mean number density of Core 2 and Core 3 is  several times larger than Core 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The derived core mass ranges from 11 M⊙ to 18 M⊙.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we discuss the uncertainties of derived  mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We can get the uncertainty of continuum flux and effective radius in imfit function (∼ 10%).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The typical uncertainties of gas-to-dust ratio and dust opacity are 23% and 28 % derived in Sanhueza  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Using the online Parallax-Based Distance Calculator3, the uncertainty in the distance  is 7%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The uncertainty of dust temperature is taken to be 10 %.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Taking all these things into account,  we estimate a mass and number density uncertainty of ∼ 42% and ∼ 56%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Molecular Line Emission  Different molecular lines trace different physical conditions, providing useful information about  dense cores and their surrounding environments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The ALMA observations cover a total of ∼8 GHz  bandwidth in four spectral windows, detecting many molecular lines in dense cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We show the  spectra of three identified cores and discuss their chemical differential in Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The differential  of line richness suggests an evolution path from Core 1 to Core 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Figure 3 shows the integrated intensity map of molecular lines used in our analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Since CO, SiO  and H2CO trace more extended emission, deuterated species are good dense gas tracers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We cut the  image at the primary beam response of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2 for CO, SiO, H2CO, and 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 for deuterated molecular  lines, leading to little differences in field of view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The integrated velocity ranges from -15 km s−1 to  30 km s−1 for CO and SiO, 4 km s−1 to 20 km s−1 for three para-H2CO lines, and from 8 km s−1 to  16 km s−1 for three deuterated molecular lines (DCN, DCO+, N2D+).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The spatial distribution of CO and SiO is mainly associated with outflow activities and less as-  sociated with continuum emissions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Note that SiO emission can also be emitted by accretion disks  (Maud et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2018).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In our analysis, we exclude the possibility because of the large spatial scales  (> 104 AU).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Previous studies suggest H2CO lines can be used to trace not only the compact cores  but also outflows (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Tychoniec et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2019;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Beuther et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021), which is consistent with our  observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The spatial distribution of three deuterated lines mainly agrees with the continuum  emission, indicating that the three molecular lines are good dense gas tracers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Outflow Properties  The outflow signatures of three compact cores are revealed by CO (2-1) and SiO (5-4) emission.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  To identify the outflows, we concentrate on blueshifted and redshifted CO and SiO emission relative  to the systematic velocity of the sources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Figure 4 shows the velocity-integrated emission map and  identified outflow lobes of CO (2-1) and SiO (5-4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The detailed process of outflow identification for  the complex CO emission is shown in Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' A slight difference has been noted in the number  and orientation of the identified lobes using these two tracers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Note that CO and SiO have different  excitation temperatures and thus, a slight difference in the identified lobes is possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  We find  explicit bipolar outflow activities towards Core 2 and Core 3, indicating the two cores are associated  with ongoing star formation activities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We also find more than one group of outflows associated with  Core 3, which implies that there may be multiple driving sources within this core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In addition, we  find a possible weak CO outflow around Core 1 that is however lower than the velocity range we had  3 http://bessel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='vlbi-astrometry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='org/bayesian  9  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' CO and SiO outflows of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 after primary beam correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The grayscale background image  shows the ALMA 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm continuum emission.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue ellipse in the bottom-left marks the beam area  of the continuum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The cyan ellipse marks the position of the cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (a): CO outflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue and red  contours show the blueshifted and redshifted CO emission integrated over [-7, 8] km s−1 and [14, 29] km s−1,  at levels of [3, 15, 30, 50, 100, 200]σ and [6, 15, 30, 50, 100, 200]σ, where σ equals to 2 K km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (b): SiO  outflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue and red contours show the blueshifted and redshifted SiO emission integrated over [-10,  10] km s−1 and [14, 34] km s−1, at levels of [3, 6, 9, 12, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=']σ, where σ equals to 1 K km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue and  red arrows mark the directions of outflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  defined for characterizing outflow emission.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Also, it may be attributed to side lobe contamination or  an extension of outflow lobe o3a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Therefore, the evolutionary phase of Core 1 is uncertain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Since the emission from CO lobes is tangled and it is difficult to distinguish them from each other,  we use SiO data to estimate the outflow parameters only for those lobes that are identified in both  tracers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For the red lobe of outflow 3a, we assume that the observed emission is associated with Core  3 rather than Core 1 because of two possible reasons.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' First, no blue lobes are identified for Core 1 in  SiO and second, the intensity of the blue lobe of 3a is strong enough to make us consider that the red  emission only corresponds to the red lobe of 3a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We calculate the SiO column density according to  the equation from Mangum & Shirley (2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Assuming that the beam filling factor equals to 1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' SiO  emission is optically thin,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' the temperature of the background source is negligible,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Rayleigh–Jeans  approximation and local thermodynamic equilibrium (LTE) conditions can be applied,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' we can get  the following equation:  Ntot = (  3kB  8π3νSµ2  d  ) ( Qrot  gJgKgI  ) exp( Eu  kBTex  )  �  TBdv  (3)  where kB is the Boltzmann constant,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' ν is the rest frequency of the SiO (5-4) transition,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' S is the line  strength,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' µd is the permanent dipole moment of the molecule,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Qrot is the partition function of the  molecule,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' gi are the degeneracies,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Eu is the energy of the upper energy level,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Tex is the excitation  temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we can simplify the equation:  NSiO  �  cm−2�  = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='54 × 1010 (Tex + 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='347) exp  �31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content="26  Tex  � �  TBdv  (4)  a) co  BO0'0  20814'50″  0." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='006  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  15\'00"  Dec (ICRS)  Jy/beam  3b  2a  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  10"  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  20"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  1809±22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5s  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0s  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5s  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0s  19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5s  RA (ICRS)0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='010  (b) SiOp  20°14\'50"  3c+  B00\'0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='006  15\'00"  Core  3h  Dec (ICRS)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  Jy/beam  3b  28  2a  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  10"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  20"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  1809±22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5s  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0s  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5s  20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0s  19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5s  RA (ICRS)10  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  In our calculation, we assume Tex ≈ Tkin,NH3=18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Then we can derive the outflow parameters  following the similar procedure reported in Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2011) and Baug et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2021):  Mout =  d2  �  SiO  H2  �µmH  �  Ω  NSiO (Ω′) dΩ′  (5)  Pout = Moutv ×  1  cos i  (6)  Eout = 1  2Moutv2 ×  1  cos2i  (7)  tdyn = lflow  vLobe  × cos i  sin i  (8)  ˙Mout = Mout  tdyn  × sin i  cos i  (9)  where d is the kinetic distance to G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21, which is taken to be 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 kpc (Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017),  �  SiO  H2  �  is  the SiO abundance relative to H2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In our calculation, we set the value to be 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8 × 10−10, which is  the average SiO abundance for infrared-quiet sources in Csengeri et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Note that the SiO  abundance may be enhanced in outflow regions and vary greatly in different regions, which may cause  a few orders of magnitude difference from 10−12 to 10−8 (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2019b;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Lu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The v is  the velocity of the outflow relative to the systematic velocity of driving source in the line of sight and  the systematic velocity is determined by N2D+ line fitting (11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 km s−1 for Core 2 and 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 km s−1  for Core 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' lflow is the maximum distance between the extent of outflow lobe and the central source  projected to the plane of sky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In addition, vlobe is the maximal velocity offset in the line of sight of  the outflow lobe relative to the driving source and i is the inclination angle between the outflow jet  and the line of sight, which is set to be an average value of 57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3◦ assuming all orientations are equally  favorable (see Bontemps et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 1996 for detailed calculation).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Derived Outflow Parameters  Parametera  o2a  o3a  o3b  o3cb  Blue  Red  Blue  Red  Blue  Red  Blue  v (km s−1)  [-11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9, 10]  [13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9]  [-4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0]  [13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8]  [-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0]  [13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9]  [-5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 10]  Mout (M⊙)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='58  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='38  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='81  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='09  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='93  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='79  Pout (M⊙ km s−1)  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='37  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='98  152.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='43  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='71  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='40  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='13  Eout (M⊙ km2 s−2)  194.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='28  1450  171.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='76  220.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  509.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  lflow (pc)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='17  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12  tdyn (103 yr)  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='07  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='87  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='24  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='03  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='31  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33  ˙Mout (10−4 M⊙ yr−1)  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='36  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='62  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='84  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='39  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='38  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='67  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='43  a: All the values except lflow have been corrected for inclination.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  b: No SiO red lobe is detected for outflow o3c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 3 lists the derived outflow parameters with the correction of inclination.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Here we use a  single excitation temperatures for all the outflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In fact, the excitation temperature may be very  11  different in different parts of outflow lobes (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Green et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We test the different excitation  temperature in a range of 15-50 K and find that it would cause a maximum of ∼ 20% difference to  our estimated parameters, which indicates the variations of excitation temperature only have a small  effect on results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' To check the validity of optically thin assumption, we derive the optical depth of  SiO line using the RADEX4 Non-LTE molecular radiative transfer online tool.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Because the profile  of SiO is not gaussian, we use the Moment-2 value of each outflow lobe as velocity dispersion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  regions of outflow lobes are away from the center of cores, the number density of the H2 gas would  be much smaller than the average number density of each core, which is taken to be 104cm−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We  use our derived SiO column densities to calculate the optical depth of each lobe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The derived optical  depths are smaller than 1 (range from 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='06 to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='79), except for o3a, which indicates that the optically  thin assumption of SiO is relatively reasonable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For outflow o3a, the two lobes are optically thick,  resulting in underestimations for the derived parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The outflow mass-loss rates in Table 3 are in orders of 10−4 M⊙ yr−1, comparable to the outflow  mass-loss rates observed in several high-mass star forming regions (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2005;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Wang  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2014;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017), while they are more than three order magnitudes higher than those  in low-mass star formation regions (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Phan-Bao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2014;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Santamar´ıa-Miranda et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Assuming outflows are powered by accretion disks, we can infer the mass accretion rates according  to the outflow force derived from SiO (5-4) (Bontemps et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 1996):  ˙Macc =  1  fent  ˙Macc  ˙Mw  1  Vw  Pout  tdyn  (10)  where fent is the entrainment effiiciency relating the SiO outflow source to the momentum flux of the  wind at its source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The value of fent is typically in range of [0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='25] and we take it as 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='25 (Liu  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  ˙Mw  ˙Macc is the ratio of the wind/jet mass-loss rate to the mass accretion rate and the typical  value is ∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 based on magneto-hydrodynamic models (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Konigl & Pudritz 2000;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Cabrit 2009).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  After assuming a typical jet/wind velocity of Vw ∼ 500 km s−1, we can estimate the total accretion  rates of o2a, o3a, o3b, o3c are about 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 × 10−4, 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 × 10−4, 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2 × 10−4, 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 × 10−4 M⊙ yr−1 and the  uncertainties of the estimated mass accretion/outflow rates are mainly caused by the uncertainties  of the parameters discussed above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Compared to previous studies, the mass accretion rates here are  comparable to some massive star formation models (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', McKee & Tan 2003;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2010) and  some other outflow studies in high-mass star forming regions (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2005;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Qiu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2009;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Lu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2018).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The uncertainties of derived outflow parameters can come from many aspects such as the SiO  abundance, outflow inclination angle, error in measurement, optically thin assumption, and adopted  excitation temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we only consider the uncertainties caused by three main aspects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' First,  the typical uncertainty of SiO abundance is considered to be a factor of 10 (∼ 1 dex), and the  maximum value can be up to two order of magnitudes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Second, considering an angle range from  15 degrees to 75 degrees, the uncertainty caused by inclination angle will range from 2 to 5 due  to the different formula forms about angles (∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 dex).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Third, the error in measurement is  considered to be 50% (∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2 dex), including uncertainties of flux and distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Taking all these  things into account, we estimate an uncertainty of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5-1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 dex (a factor of 30-80) in the derived  4 http://var.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='sron.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='nl/radex/radex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='php  12  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  outflow and accretion parameters except for the dynamical timescale, and note that the uncertainty  will be even larger in some regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Because of the large uncertainties, we will not discuss these  results further.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The uncertainty of dynamical timescale only comes from the inclination angle and  the error in measurement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We do not detect SiO outflow around Core 1 and the dynamical timescale  of Core 2 and Core 3 is about 103 and 104 years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' From the calculation of dynamical timescale, we  derive an evolutionary picture from Core 1 to Core 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we perform a Monte Carlo simulation  to test the credibility of this conclusion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Assuming all orientations are equally favorable between 15  degrees to 75 degrees and adding an additional 50% error of measurement, the probability that this  conclusion still holds is ∼ 97%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' So the evolutionary sequence from Core 1 to Core 3 derived from  dynamical timescale is relatively credible after considering the uncertainties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Dense Core Structure  Using the combined ALMA 12m+7m continuum image, we can measure the intensity profiles of  each core at 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm wavelength.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We calculated the averaged intensity profiles in annuli with a width  of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′ as a function of the projected distance to the core center (from 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4′′ to 4′′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Because the  maximum recoverable scale for 7 m data is 36′′, greatly larger than the core size, we can ignore the  effect of missing flux.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We smooth the continuum image to a circular beam of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='72′′ ×1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='72′′ in advance  to eliminate the effect of the elliptical beam shape.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In order to estimate the density profile and derive  the dynamical properties of each core, we assume that the density and temperature profiles both have  power-law function forms: ρ = ρ0 (r/r0)−p and T = T0 (r/r0)−q within a maximum core radius rmax.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Under optically thin assumption, and Rayleigh–Jeans approximation, the intensity profiles can be  derived analytically following the relation: Iν(r) ∝ r1−(p+q) (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Beltr´an et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2002).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The fitting  results are listed in Table 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Because the optically thin assumptions may not be accurate for compact cores, we carry out  radiative transfer analysis using RADMC-3D (Dullemond et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2012) and compare the results with  the observations to give a more accurate estimation of dense core structures and virial states.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here  we briefly describe our models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We assume that both of the density and temperature profile have a  power-law function form within a maximum core radius of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 pc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' If the core is internally heated, the  temperature profile index q equals to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33 (Scoville & Kwan 1976).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' However, for the edge part in our  model, the external heating effect from the nearby HII regions can play an important role and we  set the lowest dust temperature as 10 K in our models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We use the temperature derived in Section  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 to estimate temperature structures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For Core 1, we set T0 = 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='64 K and q = 0 because there is  no clear evidence of internal heating.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For Core 2 and 3 with clear internal heating evidence, we set  q = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33 and T0 equals to 79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 and 58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8 K, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' There is no necessity to consider the index  of dust opacity law because we only have dust continuum at a single wavelength.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We assume dust  opacities with the value of κ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='90 cm2 g−1 at 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm for 106 cm−3 and range in different densities  based on the OH5 models in Ossenkopf & Henning (1994).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  In summary, we need to fit two free parameters, the density in the reference radius r0 (ρ0) and the  density profile index (p).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The value of r0 is arbitrary and we set r0 = 2000 AU (∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='01 pc) in our  calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The fitting procedure is similar to some previous studies (S´anchez-Monge et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2013;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Palau et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  2014).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We make the sampling in two-dimensional parameter space and calculate the residuals in  13  Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Best-fit intensity profiles of three cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue line is the best-fit model and the blue points are  the observational results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The grey dashed line represents the response of the beam and the black horizontal  dotted line marks the 3σ noise levels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Core 1 best-fit mode  102  Intensity(Mjy/sr)  101  10-2  10-1  r(pc)Core 2 best-fit mode  102.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Intensity (Mjy/sr)  101  10-2  10-1  r(pc)Core 3 best-fit mode  102  Intensity (Mjy/sr)  101  10-2  10-1  r(pc)14  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Best-fit Parameters of Dense Core Structures  Core  q  ρ0a  pa  χ2  min  χr  p1b  (g cm−3)  (RADMC)  (analytical)  1  0  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5) × 10−19  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='36 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='22  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='18  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='44  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='67 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='08  2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33  (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2) × 10−19  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='70 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='24  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='43  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='75 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='09  3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2) × 10−19  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='48 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='18  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='48  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='64  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='63 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='10  a: free-parameters fitted in RADMC-3D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  b: density profile index derived from analytically relation: Iν(r) ∝ r1−(p1+q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  every step:  χ2 ≡  n  �  i=1  �yobs  i  − y mod  i  (ρ0, p)  σi  �2  (11)  The initial value is set to be p = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5, ρ0 = (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0) × 10−18 g cm−3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We run 1000 samples  in one loop to find the best-fit values and reduce the step length by 20% in the next loop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  final best-fit parameters are selected after ten loops which consist of 10000 models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For the fitting  with two free parameters, the uncertainty of each parameter can be estimated within the limit:  ∆χ2 = χ2 − χ2  min < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We show the best-fit results in Figure 5 and list the best-fit parameters in  Table 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Comparing the fitting results with analytical solution, we find that the analytical solution  would overestimate the density profile index by 3% − 20%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Considering the possible CO outflow in  Core 1, we also test the model that Core 1 is in protostellar phase.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We set q=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33 and maintain other  parameters, and the derived density profile index and analytical results are 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='95 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='26 and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='34 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='08.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The density profile index is also underestimated and the proportion of underestimation reaches  ∼ 40%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The reason for the systematic difference is that the optical depth is assumed to be constant  in the analytical solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In fact, the optical depth is a function of the radius, decreasing as the  radius increases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The density profile index ranges in 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='36−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='70, consistent with previous results of  massive cores in high-mass star forming regions on 103 − 105 au scales (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Butler  & Tan 2012;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2019a;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Gieser et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Dynamical States of Cores  Studies have shown that the abundance of N2D+ remains high in the very early evolutionary stage  of star formation (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Crapsi et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2005;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Kong et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2015) and N2D+ is a good tracer to probe the  dynamical states of prestellar/protostellar cores (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Kong et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' To derive the dynamical  states and virial parameters of continuum cores, we need to fit N2D+ spectra within three cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We  use Pyspeckit (Ginsburg & Mirocha 2011) to fit hyperfine structures of N2D+, deriving the centroid  velocity and velocity dispersion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Under the optically thin assumption, the upper limit of optical  depth is set to be 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 (the rationality of optically thin assumption can be seen in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 for  RADEX analysis).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  We detect N2D+ in all three cores and the N2D+ spectra of three cores are  shown in Figure 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core 2 and Core 3 have a single velocity component and Core 1 has two velocity  components higher than 5σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We make N2D+ channel maps in Appendix C to visualize the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' As  the Figure 13 shows, all the velocity components are associated with the central cores and the two  velocity components in Core 1 are not spatially resolved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For Core 1 with two velocity components,  we estimate the gas mass of each velocity component assuming the continuum flux is proportional  15  Figure 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core-averaged fitting results of N2D+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The red line is the best-fit results and the green line is  the fitting residual shifted by 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The texts in the upper right are the best-fit parameters of hyperfine  structures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Core 2 N2D+ Spectrum  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  Tex(0)=  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='85 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='38  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  =(0)1  v(0)=  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='448 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='039  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  g(0)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='28 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  5  10  15  0  20  25  Velocity (km s-1)Core 3 N2D+ Spectrum  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='23 ±  Tex(0)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='17  t(0)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  v(0)=  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='235 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='023  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='377 ±  g(0)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='023  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  10  0  5  15  20  25  Velocity (km s-1)Core 1 N2D+ Spectrum  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  Tex(0)=  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='95 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='37  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  t(0)=  v(0)=  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='643 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='026  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  g(0)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='235 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='024  Tex(1)=  15  t(1)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='060 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='008  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  v(1)=  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='133 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='094  g(1)=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='58 ±  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='11  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  10  15  0  5  20  25  Velocity (km s-1)16  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core Dynamical Parameters  Core  Component  v  σobs  σtot  Mvir  Mgas  αvir  Ms  (km s−1)  (km s−1)  (km s−1)  (M⊙)  (M⊙)  1  1  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='58±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='11  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='61±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='11  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3±2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7±2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8±1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  2  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='24±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='30±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='02  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8±3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  2  1  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='28±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0±5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  3  1  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='38±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='42±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='02  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2±7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1  to the velocity-integrated intensity of the velocity component.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Then we can derive the virial mass of  each core (see details in Bertoldi & McKee 1992;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2013):  Mvir = 5  αβ  σ2  tot reff  G  (12)  where parameter α = (1 − b/3)/(1 − 2b/5) is the correction to virial estimates for a power-law  density profile ρ ∝ r−b (MacLaren et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 1988), β = arcsin e/e is the geometry factor determined by  eccentricity, reff is the effective radius of each core, σtot is the total velocity dispersion and can be  derived as:  σtot =  ��  σ2  obs − ∆2  ch/(2  √  2 ln 2)2 − σ2  th,N2D+  �  + σ2  th,µmH  (13)  where σth,µmH = cs =  �  kBT  µmH.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Then we can derive the virial parameter αvir = Mvir/Mgas of each  velocity component in compact sources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The uncertainties of dynamical parameters mainly come  from three aspects: uncertainties of effective radius, uncertainties of derived velocity dispersion, and  uncertainties of derived density profile index.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The uncertainties of gas mass can be derived in Section  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Considering the possible difference of N2D+ abundances in different velocity components of Core  1, we add an additional 20% uncertainty in gas mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' As can be seen in Table 5, for the two cores with  SiO outflow activities (Core 2 and Core 3), αvir is smaller than 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5, which means that the two cores  are gravitationally unstable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For the core at the earliest evolutionary stage (Core 1), the component  with high centroid velocity is likely to undergo gravitational collapse and the component with low  centroid velocity is in a critical state bound by gravity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' If we consider the Core 1 at protostellar  stage and apply b=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='95±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='26 into calculation, the derived virial parameters will be 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9±1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 and  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3±0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 for component 1 and component 2, respectively, which would not affect our conclusions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The different dynamical states may indicate unresolved structures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In addition, we also calculate the  Mach number using Ms =  √  3σnt,N2D+/cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' All the Mach numbers are higher than 1, which indicates  general supersonic turbulence in this star-forming region.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Deuterium Fraction  Previous studies found that the deuterium fraction of N2H+ decreases with time after protostellar  stages (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Fontani et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Gerner et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In this section we calculate the deuterium  fraction of N2H+ in three cores using SMA data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The SMA data covers both N2H+ and N2D+  lines, which provides good opportunities to compare our results with previous studies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Because the  cores are barely resolved in these lines, we extract the spectra of N2H+ and N2D+ at the center  17  Figure 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Left: Moment-0 maps of the N2D+ and N2H+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The integrated velocity ranges from 8 km s−1  to 15 km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The white ellipse in the bottom left marks the SMA synthesized beam.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The black crosses  represent the position of the core center identified in ALMA data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Right: The spectra of the N2D+ and  N2H+ extracted from the pixel where the core center is.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Table 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Deuterium Fraction of N2H+  Core  σT (N2D+)  NN2D+  σT (N2H+)  NN2H+  [N2D+/N2H+]  (K)  (1011 cm−2)  (K)  (1011 cm−2)  1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='036  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='102  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='93 (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='62)  2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='032  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8 (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='088  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='19 (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05)  3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='032  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='100  46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15 (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='03)  of cores which are identified in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Figure 7 shows the integrated emission maps and the  extracted spectra of three cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We calculate the N2H+ and N2D+ column densities using equation  4 under the same assumptions with the excitation temperature equals to 15 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In this calculation we  don’t distinguish the two velocity components in Core 1 as mentioned in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We also use the  RADEX Non-LTE molecular radiative transfer tool to check the validity of optically thin assumption.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  N2D+(3-2)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  20°14\'50"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 Core  15\'00"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  (2000)  Core 3  Dec  Core 2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  K  10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  20=  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  18^09m225  2i5  205  RA (J2000)  N2H+ (3 - 2)  6  20°14\'50*  +  Core1  15\'00"  (J2000)  2  Core3  Dec  Core 2  10"  0  2  20  18°09m22s  2is  205  RA (J2000)Core 1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  N2D +  N2H+  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  Core 2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  N,D +  N2H+  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  N,D +  N2H+18  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The abundance of N2H+ is much higher than N2D+, using the derived column densities of N2H+,  we find the optical depth of each hyperfine component ranges from 10−4 to 5 × 10−2, indicating the  optically thin assumption is reasonable for all three cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' To estimate the uncertainties of column  densities, we use Monte Carlo method by adding to each pixel a gaussian noise centered at 0 K, with  a standard deviation of σT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Note that we mask the data points in Core 1 where Tb < 0 K because  of the effect of side lobes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We repeat the calculations for 1000 times and take the standard deviation  as the uncertainties of column densities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We list the final results in Table 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Although a low signal-  to-noise ratio of N2H+ cause an unreliable estimate of uncertainty for Core 1, the decreasing trend  of deuterium fraction is clearly evident in the spectra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' This indicates an early to late evolutionary  sequence from Core 1 to Core 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' DISCUSSION  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Potential Bias from Temperature Estimation  In our analysis, we apply a uniform temperature to each core using the dust temperature of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  However, we find SiO outflow activities in Core 2 and Core 3, which indicates that the three cores in  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 might be at different evolutionary stages.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' It is a crude assumption to consider a single dust  temperature for all the cores and here we would like to give a correction to the temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Besides  NH3, H2CO lines can also be used as a thermometer in dense molecular clouds (Mangum & Wootten  1993).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The H2CO lines around 218 GHz are easily measured and widely used in high-resolution  interferometric observations (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Lu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Beuther et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we use the eXtended  CASA Line Analysis Software Suite (XCLASS, M¨oller et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017) to fit the rotational temperature  of para − H2CO lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We fit the average spectra of each core and use the Trot (H2CO) to replace the  dust temperature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The line fitting is shown in Figure 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' There is no clear detection of para − H2CO  lines in Core 1, which indicates that the dust temperature around Core 1 is relatively low.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  dust temperature applied in Core 1 is reasonable and we only apply the temperature correction in  Core 2 and Core 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' However, the para − H2CO lines are easily affected by outflow activities (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=',  G´omez-Ruiz et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2013) and the outflow lobes are very close to the core center, which suggests  that we may overestimate the dust temperature using the above correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we also apply a  temperature of 40 K (a typical temperature for protostars) towards the two cores and the results  after temperature correction are listed in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' If we consider Core 1 at the protostellar stage  and apply the temperature of 40 K to Core 1, the mass and density of Core 1 will be 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='9 M⊙ and  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 × 105 cm−3, respectively, making the mean number density of Core 1 several times smaller than  Core 2 and Core 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The uncertainties of derived parameters are similar to the previous discussion in  Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  From Table 2 we can see that the mass of two protostars becomes relatively low after applying  the temperature correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Though we consider the overestimation from the fitting of para − H2CO  lines, there are no more massive protostars in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The results may indicate that the core at the  earliest stage contains the maximal mass, which is in contrast with the competitive accretion model  (Bonnell et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2001).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' However, we don’t know what percentage of the gas can eventually be fed  into the collapse of the core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The evolution path of Core 1 still needs to be further explored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  density of dense cores at different evolutionary stages is comparable after applying the temperature  correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Kong et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2021) investigate density change during high-mass star formation and find  19  Figure 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core-averaged fitting results of para − H2CO lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The black line is the best-fit results and red  line marks the residual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The line around 218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='43 GHz is one of CH3OH lines which is not covered in this fit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Here we mask the residual of this line in the figure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Core 1  Fit  3  Observation  X-1K  2  K  0  1  218800  218000  218200  218400  218600  219000  219200  Frequency (MHz)Core 2  Trot (H2CO) = 83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0 K  Fit  3  Observation  X-1K  2  K  0  1  218000  218200  218400  218600  218800  219000  219200  Frequency (MHz)Core 3  Trot (H2CO) = 67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='7 K  Fit  3  Observation  X-1K  2  K  7  0  1  218000  218200  218400  218600  218800  219000  219200  Frequency (MHz)20  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Figure 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Left: Moment-0 maps of the three deuterated molecules after primary beam correction overlaid  with 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm continuum map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The blue, yellow, red contours represent the emission of N2D+, DCN, DCO+,  at levels of [3, 5, 7, 9,.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=']σ, where σ equal to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='62, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='45, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='47 K km s−1, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Right: Core-averaged  spectra of the three deuterated molecules within the three compact cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  no difference when comparing the populations at different evolutionary stages, consistent with our  results in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Gas Fragmentation  Fragmentation exists at different scales from giant molecular clouds to small gas clumps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In Section  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, we find clear fragmentation in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 and we will discuss how this source fragments into dense  cores that have the potential to form high-mass stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  If the fragmentation is dominated by thermal Jeans instability (Jeans 1902), the separation between  the cores and the mass of cores will be comparable to the Jeans length and Jeans mass of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  We calculate the Jeans length and Jeans mass following Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2014):  λJ = cs  � π  Gρ  �1/2  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='066 pc  � T  10 K  �1/2 �  n  105 cm−3  �−1/2  (14)  MJ = π5/2c3  s  6  �  G3ρ  = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='877 M⊙  � T  10 K  �3/2 �  n  105 cm−3  �−1/2  (15)  where the temperature T is the kinetic temperature derived from ammonia in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 and density  n is the average density of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 (Yuan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2017).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The Jeans length and Jeans mass of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21  is about 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='04 pc and 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='97 M⊙.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In our sample, the initial fragmentation leads to three massive cores  with masses from 11 to 18 M⊙ with an average separation of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12 pc in the plane of sky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Considering  the projection effects, the mean separation would be even larger than 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='12 pc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The large difference  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content="008  20-14'55  Core 1  0." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='006  0  15\'D0"  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  tooozn :  Jy/beam  Core 3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  05"  N2D +  Core 2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='000  DCN  1g*  DCO+  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='002  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='004  18*0921.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content="0*  20'5*  20." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0*  RA (JZDOO)N2D +  DCN  DCO+  >>>>>>>>?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  ><>>>>  20  10  20  30  40  N2D +  DCN  DCO  20  10  10  20  30  40  N2D +  DCN  DCO+  >>>>>21  Figure 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The relation between fragment mass and nearest separation distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The grey downwards  triangles mark the data of G28-P1 (Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The grey upwards triangles represent the data of G30-  C2 (Zhang & Wang 2011).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The grey circles show the data of G11-P1 and G11-P6 (Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2014).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  blue crosses and orange crosses mark the data in our work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The orange shaded regions show the sensitivity  and resolution limit of the our ALMA observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The dotted line shows thermal Jeans fragmentation  with T = 18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 K and n = [102, 108] cm−3, and the blue shaded region corresponds to the same density  range but with T = [10, 30] K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The solid line shows a scale-free turbulent Jeans fragmentation with effective  temperature Teff of 175 K (total velocity dispersion σ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='78 km s−1) and the same density range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The green  shaded region corresponds to the same density range but with Teff = [46, 413] K (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', σ = [0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2] km s−1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The sizes indicate the physical scales of grey data points: the smallest are condensations (∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='01 pc),  the middle are cores(∼ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 pc), and the largest are clumps(∼ 1 pc).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' This figure shows clearly that the  fragmentation in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 are likely dominated by turbulence over thermal pressure at core scales under the  sensitivity of our observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  indicates that the fragmentation is not only controlled by gravity and thermal pressure, which is  consistent with the conclusion derived in Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  104  Thermal Jeans fragmentation  Scale-free turbulent Jeans fragmentation  G28-P1 (Wang+2011)  G30-C2 (Zhang+2011)  103  G11-P1/6 (Wang+2014)  G1o.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21-Cores (this work)  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21  102  G1  of  101  condensation (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='01 pc)  core (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 pc)  clump (1 pc)  tial  100  Spat  MassSensitivityofG1021  10-1  10-2  10-1  100  101  Nearest Separation (pc)22  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  If we replace the cs by the total velocity dispersion of NH3 measured in Wienen et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2012)  (σ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='78 km s−1), we can calculate the effective Jeans length and Jeans mass with the support of  thermal pressure and turbulence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' To investigate the role of turbulence in gas fragmentation, we use  the similar method from Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2014) to visualize the relation between fragment mass and  nearest separation distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The results are shown in Figure 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' This figure includes data points  from previous relevant works at different spatial scales that can be compared with our measurements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The shaded blue region represents the thermal Jeans fragmentation domain where the adopted tem-  perature and density are in ranges T = [10, 30] K and n = [102, 108] cm−3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The shaded green region  represents the turbulent Jeans fragmentation domain with the same density range and effective tem-  perature range Teff = [46, 413] K (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' total velocity dispersion σ = [0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2] km s−1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' From Figure  10 we can conclude that the fragmentation in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 is likely dominated by turbulence over thermal  pressure at core scales within the sensitivity bounds of our observations, which is consistent with  several previous works (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2009;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Pillai et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011, 2014).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Recent  high-resolution observations down to the smallest accessible spatial scales find high-level fragmen-  tations, more consistent with thermal Jeans fragmentation of dense cores (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Palau et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2018;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Beuther et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2019;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Tang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  We cannot exclude the possibility that these cores may  harbor further fragmentations not resolved, especially the SiO outflow image and different velocity  components are consistent with the possibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Further high resolution observations are needed to  investigate the fragmentation mechanism at smaller scales.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Deuterated Molecules as Chimecal Clocks  Deuterated molecules are sensitive to temperature, which can provide useful information to probe  the initial conditions (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Bacmann et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2003;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Pillai et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2007;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Because of the  different formation mechanisms, different deuterated species trace sources in different evolutionary  stages.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For example, the abundance of N2D+ will decrease after the onset of star formation (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=',  Caselli et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2002;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Fontani et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011), while DCO+ and DCN are more likely to be detected in  warm environments (Gerner et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2015).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The combination of the three deuterated molecules can  be treated as chemical clocks, which has been proven by recent observations (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=', Morii et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Sakai et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Figure 9 shows the distribution of the three deuterated molecules overlaid with the 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 mm con-  tinuum map and the spectra of the three cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core 1 shows strong N2D+ emission but no DCO+  and DCN emission, which is considered at the earliest evolutionary stage in star formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Core 2  exhibits weak N2D+ and DCO+ emission, which indicates the core has just ignited star formation  activities for a short period.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Meanwhile, we can see clear DCN and DCO+ emission and weak N2D+  emission within Core 3, which suggests Core 3 is at the latest evolutionary stage of star formation  among the three cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Here we estimate an evolutionary sequence from Core 1 to Core 3, consistent  with the results derived from outflow activities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We don’t give a quantitive correlation between the  ratio of deuterated molecules and the dynamical timescale due to insufficient sample size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Detailed  studies of the relation need to be investigated in a larger sample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The Potential for High-mass Star Formation  G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 is considered as a high-mass starless core candidate, which is at the earliest stage of high-  mass star formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In this section we will discuss whether high-mass stars can form in this source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  23  According to Kauffmann & Pillai (2010), the region which has the potential to form high-mass  stars should follow the relation: m(r) ⩾ 580 M⊙(r/pc)1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='33, after rescaling the dust opacities without  the factor of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 reduction (see the discussion in Dunham et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' 2011).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Applying the equivalent  radius r=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='13 pc to the equation, the derived mass threshold is 38 M⊙.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The mass surface density  is another widely used parameter to estimate the potential of high-mass star formation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Urquhart  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2013) suggest an empirical threshold for high-mass star formation of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='05 g cm−2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The mass  and surface density of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 are estimated to be 314 M⊙ and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='28 g cm−2, greatly exceeding the  above thresholds, which indicates that G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 has enough potential to form high-mass stars.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Since high-mass stars could form in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21, we can estimate the possible maximum stellar mass  using the properties of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Based on the empirical relation mentioned in Larson (2003):  �  mmax  M⊙  �  = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  �  Mcluster  M⊙  �0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='45  , assuming a 30% star formation efficiency, G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 could form a stellar  cluster with a total stellar mass of 94 M⊙.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The derived maximum stellar mass is 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 M⊙.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Sanhueza  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' (2017) suggests another relation to estimate the maximum stellar mass using the the IMF from  Kroupa (2001):  mmax =  �0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  ϵsfe  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3  Mclump  + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5 × 10−3  �−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='77  M⊙  (16)  Using the same 30% star formation efficiency, a high-mass star with the mass of 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1 M⊙ could form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  In Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1, the derived mass of identified cores ranges from 11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5-17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2 M⊙, slightly larger than the  derived maximum stellar mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The comparison indicates further fragmentation at smaller scales,  which is consistent with our results (multiple outflows in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3 and velocity components in  Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Here we propose a possible evolutionary picture of G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 is at a very early evolutionary  stage of high-mass star formation due to its short dynamical timescale.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  It fragments into three  dense cores, among them Core 3 starts the star-forming activities first and Core 1 is at the earliest  evolutionary stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' No high-mass prestellar core is found in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Based on our results, we predict  the three dense cores would fragment into more gas condensations at smaller scales.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' High-mass stars  will eventually form in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 upon the completion of gas accretion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' CONCLUSION  We study the fragmentation, core properties and chemical evolution towards a high-mass prestellar  core candidate G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21, using ALMA and SMA observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Our main findings are as follows:  (1) We found three continuum compact sources in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21, with masses ranging from 11 M⊙ to  18 M⊙ at a uniform dust temperature of 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='6 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We find a coherent evolutionary sequence from  Core 1 to Core 3, based on line richness, outflow properties, deuterated molecules distribution, and  deuterium fraction of N2H+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' No high-mass prestellar core is found in this source.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' This suggests a  dynamical star formation where cores grow in mass over time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  (2) Several outflows are identified in SiO (5-4) and CO (2-1) lines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We derive the outflow parameters  of lobes that are identified in both tracers, consistent with the previous work of other high-mass star  forming regions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The dynamical timescale of Core 2 and Core 3 is roughly 103 and 104 yr using SiO  outflows and we derive an evolution picture from Core 1 to Core 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  (3) We derive the core structures using radiative transfer tools and compare the density profile index  with it derived from the typical analytical method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The results are comparable, while the analytical  method may overestimate the index by 3% − 20%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We also derive the virial parameters using the  24  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  above index, finding different virial status of different cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  In addition, all the Mach numbers  are higher than 2, suggesting general supersonic turbulence in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Turbulence is considered to  play important roles in fragmentation at core scales in G10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='21 within the sensitivity bounds of our  observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  (4) We derive the deuterium fraction of N2H+ using SMA data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The deuterium fraction of N2H+  decreases with the evolution of cores, which is consistent with previous works.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We also derive similar  conclusions through the spatial distributions of three deuterated molecules observed by ALMA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The  combination of three deuterated molecules and outflow activities can be treated as chemical clocks,  which need to be investigated quantitively in a larger sample in the future.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  ACKNOWLEDGEMENTS  We are grateful to an anonymous referee for the constructive comments that helped us improve this  paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We acknowledge support from the China Manned Space Project (CMS-CSST-2021-A09, CMS-  CSST-2021-B06), the National Key Research and Development Program of China (2017YFA0402702,  2019YFA0405100), the National Science Foundation of China (11973013, 11721303), and the High-  Performance Computing Platform of Peking University.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  TGSP gratefully acknowledges support  by the National Science Foundation under grant No.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  AST-2009842.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  TB acknowledges support  from S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Bose National Centre for Basic Sciences, under the Department of Science and Tech-  nology, Government of India.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  This research has made use of the NASA/IPAC Infrared Science  Archive, which is funded by the National Aeronautics and Space Administration and operated by  the California Institute of Technology.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  This paper also makes use of the following ALMA data:  ADS/JAO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='ALMA#2016.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='01346.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' ALMA is a partnership of ESO (representing its member states),  NSF (USA) and NINS (Japan), together with NRC (Canada), MOST and ASIAA (Taiwan), and  KASI (Republic of Korea), in cooperation with the Republic of Chile.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The Joint ALMA Observatory  is operated by ESO, AUI/NRAO and NAOJ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Facilities: ALMA, SMA, Spitzer, Herschel, APEX  APPENDIX  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' SPECTRA EXTRACTED FROM CORES  Figure 11 shows the spectra extracted from identified cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The typical warm gas tracers such as  CH3OH and H2CO are detected in Core 2 and Core 3, indicating their protostellar properties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' This  deduction is consistent with the observations of outflows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' No organic molecule emission is detected  in Core 1, suggesting it at a very early evolutionary stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Detailed discussion about the three  deuterated molecules is described in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' We find a clear trend in line richness from Core 1  to Core 3, changing from poor to abundant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Chemical difference is evident in the spectra of three  cores, related to their different chemical ages.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' CO OUTFLOW IDENTIFICATION  The CO maps show complicated emission structures, which is difficult to identify outflow activities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  We identify the CO outflows through carefully visual inspection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In order to detect the possible weak  outflow lobes, we mask the strong environmental emission and check the channel maps around each  core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Each identified lobe need to be detected over twenty channels (≥ 7 km s−1) with enough  25  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  ALMA Core1  C18O  CO  N2D+  Prestellar?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  H2CO  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
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+page_content='0  C18O  CO  N2D+  ALMA Core2  Protostellar  DCN  SiO  CH3OH  H2CO  H2CO  H2CO  Tb (K)  216.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  216.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  217.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  217.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
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+page_content='0  218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  218.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  219.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  219.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
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+page_content='5  231.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  231.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  232.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  232.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  232.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  233.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  233.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='5  Frequency (GHz)  C18O  CO  N2D+  ALMA Core3  Protostellar  DCN  SiO  CH3OH  H2CO  H2CO  H2CO  DCO+  Figure 11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Spectra extracted from identified cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The gaps separate the four ALMA spectral windows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Molecules with clear detection are labeled in the figure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  emission (≥ 10 K km s−1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' For those lobes whose driving source is difficult to estimate, we judge  them by the corresponding bipolar features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Besides the lobes that satisfy the criteria, we also find  a weak blue lobe around Core 1 (o1a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Figure 12 shows the CO channel maps from -15 km s−1 to  30 km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Though the velocity range of this lobe is smaller than 10 km s−1, we still consider it a  possible outflow lobe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Meanwhile, we can’t exclude the possibility of the effect of side lobe or the  extension of the blue lobe from o3a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' In summary, this possible outflow association makes the nature  26  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  Core 1  Core 2  Core 3  18h09m21s  20s  20°14\'50"  55"  15\'00"  05"  10"  15"  RA (ICRS)  Dec (ICRS)  5  10  15  20  25  K km s  1  Figure 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Channel maps of CO (2-1) after primary beam correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The magenta contours show the  integrated CO emission at levels of [6, 12, 24, 48, 96]σ, where σ equals to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='83 K km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The black cross  symbols represent the peak positions of compact cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The left-bottom blue ellipse represents the beam  size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  of Core 1 unclear since it could be a prestellar core or a protostellar core driving an outflow at an  earlier phase than Core 2 and 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  27  Core 1  Core 2  Core 3  18h09m21s  20s  20°14\'50"  55"  15\'00"  05"  10"  15"  RA (ICRS)  Dec (ICRS)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='2  K km s  1  Figure 13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Channel maps of N2D+ (3-2) after primary beam correction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The magenta contours show the  N2D+ emission at levels of [3, 6, 9, 12, 15]σ, where σ equals to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='15 K km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The black cross symbols  represent the peak positions of compact cores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' The left-bottom blue ellipse represents the beam size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' N2D+ CHANNEL MAP  As we observe multiple velocity components of N2D+ in Core 1, we make a N2D+ channel map  to see whether the different velocity components are spatially resolved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' Figure 13 shows the N2D+  28  Jiao, Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  channel maps from 8 km s−1 to 16 km s−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content=' All the velocity components are associated with the core.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
+page_content='  The two velocity components in Core 1 are not spatially resolved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
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+page_content='1146/annurev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/hNA0T4oBgHgl3EQfH__c/content/2301.02070v1.pdf'}
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+arXiv:2301.08549v1  [cs.CL]  20 Jan 2023
+Transforming Unstructured Text into Data with Context Rule Assisted
+Machine Learning (CRAML)
+Stephen Meisenbacher∗†
+Peter Norlander∗‡
+January 23, 2023
+Abstract
+Abstract: We describe a method and new no-code software tools enabling domain ex-
+perts to build custom structured, labeled datasets from the unstructured text of documents
+and build niche machine learning text classification models traceable to expert-written rules.
+The Context Rule Assisted Machine Learning (CRAML) method allows accurate and repro-
+ducible labeling of massive volumes of unstructured text. CRAML enables domain experts
+to access uncommon constructs buried within a document corpus, and avoids limitations of
+current computational approaches that often lack context, transparency, and interpetability.
+In this research methods paper, we present three use cases for CRAML: we analyze recent
+management literature that draws from text data, describe and release new machine learn-
+ing models from an analysis of proprietary job advertisement text, and present findings of
+social and economic interest from a public corpus of franchise documents. CRAML produces
+document-level coded tabular datasets that can be used for quantitative academic research,
+and allows qualitative researchers to scale niche classification schemes over massive text data.
+CRAML is a low-resource, flexible, and scalable methodology for building training data for
+supervised ML. We make available as open-source resources: the software, job advertisement
+text classifiers, a novel corpus of franchise documents, and a fully replicable start-to-finish
+trained example in the context of no poach clauses.
+Keywords: labor markets, data creation, text classification, hybrid system, big data
+∗Equally contributing authors. We are grateful for support from the Economic Security Project Anti-Monopoly
+Fund; Loyola Rule of Law Institute; Loyola Quinlan School of Business; and Loyola University Chicago. We also
+thank Patricia Tabarani, Eric George, Steve Sauerwald, and Chris Erickson.
+†Technical University of Munich, School of Computation, Information and Technology
+‡Loyola University Chicago, Quinlan School of Business
+1
+
+1
+Introduction
+Advances in computational methods offer new ways to gain insight from large volumes of unstruc-
+tured text, and yet these methods each have significant limitations, tradeoffs, and a lack clear
+guidelines [99]. Despite the advances in Natural Language Processing (NLP), Machine Learning
+(ML), Artificial Intelligence (AI) and more recently Deep Learning (DL), there is still “the herculean
+task of finding constructs using full-text search” [79, p. 547].
+Unstructured text lack a schema, are not standardized, have multiple formats, and come from di-
+verse sources [9]. Greater attention and systematic research is needed to develop processes to create
+structured data from unstructured text [45]. A lack of structured information is a barrier to un-
+derstanding for researchers and organizations: “as much as 80% of an organization’s data is ‘dark”’
+[78]. For knowledge professionals, just-in-time access to domain specific document repositories is
+vital, but knowledge must first be codified [114]. Zettabytes (ZB) of new data are produced daily
+[20], and roughly 80% is unstructured [67]. While the manual expert labor required for qualitatively
+coding novel classification schemes is hard to scale, statistical packages, many information systems,
+and quantitative social scientists expect data to be codified and in a regular format: “tabular data
+– variables in columns, cases in rows” [80].
+ML and AI are potential solutions, but require structured training data. Hand-coding by experts
+is required in many domains, but does not easily scale. To address the disjunction between these, we
+describe a method that bridges expert-built set of context rules scaled to classify unstructured text
+and build training data for machine learning. Context Rule Assisted Machine Learning (CRAML) is
+a hybrid method for structuring textual data from large-scale corpora into datasets ready for training
+ML models and quantitative research.
+CRAML begins with a workflow common in qualitative
+manual coding research, and ends with ML models trained on text input data shaped by a qualitative
+coding scheme. CRAML is useful for qualitative and quantitative social scientists: it empowers
+domain experts to efficiently mine volumes of text and scale classification schemata, and it yields
+tabular data that captures the occurrence of concepts within a corpus of documents.
+This paper contributes to information systems research on the design of intelligent systems that
+can generate economic and social value from unstructured data [1]. By clearly defining the problem,
+managing the training data before AI is attempted, and affording users the opportunity to evaluate
+and adjust both inputs and outputs, CRAML addresses major concerns identified in research on
+AI [131]. This is the first paper to offer a thorough description of a versatile method with the
+potential to empower advanced users of an ordinary desktop computer to build machine learning
+classifiers and rectangular datasets from unstructured text according to the users’ desired scheme.
+Expert built rule-assisted machine learning models have been described in the literature, and found
+to outperform benchmark methods and professional perception in critical cases such as detecting
+persons in states of emotional distress [35]. In addition to describing the method, we call and set
+new standards for transparency and interpretability of research on text-to-data machine learning,
+and demonstrate the high utility of this approach in three applications.
+In this methods paper, we highlight the need for the CRAML tool and demonstrate its versatility
+through applications. First, we use CRAML to perform a simple literature review that highlights
+current approaches to analysis of large text corpora in five top management journals. Second, we
+release machine learning classifiers with the potential to enhance labor market efficiency, and set
+a new standard for transparency for research studying job advertisement text, where underlying
+data includes proprietary data obtained under license. We release ML classifiers, and the rules that
+created them, to enable other researchers using job advertisement text to replicate and interpret our
+approach. Last, we publish a new and massive document corpus of mandatory franchise disclosure
+2
+
+documents and present a start-to-finish analysis to enable a full replication of our process. We
+detect thousands more plausibly illegal “no poach clauses” that could violate state and federal
+antitrust law than found in earlier research [77]. We release a rectangular dataset that represents
+the prevalence of suspected no poach clauses that restrict the ability of franchise firms to recruit
+employees from other companies that belong to a franchise system. As part of the contribution of
+this work, we publish everything needed to fully replicate the no poach analysis: the original PDFs
+and the machine readable text of the franchise documents, CRAML software, the manually coded
+inputs that creates the structured, labeled data output, the training data, and a ML classifier to
+detect suspect no poach clauses.
+Section 2 reviews the well-known challenges CRAML was created to address and illustrates the
+frequency of current approaches in the management literature. Section 3 introduces and provides
+detailed motivation for our solution in the context of job advertisement text. Methodological detail
+on CRAML and empirical analysis of franchise no poach agreements is in Section 4. A more technical
+methodology is described in Appendix C. Section 5 provides future directions and discussions.
+2
+The State of the Art
+Across many fields of research, methods for analyzing unstructured text are needed. Below, we
+highlight literature in management, information systems, computational social science and com-
+puter science on: machine learning (ML), artificial intelligence (AI), natural language processing
+(NLP), topic modeling and Latent Dirichilet Allocation (LDA), linguistic inquiry and word counting
+(LIWC), computationally aided text analysis (CATA), and text or document corpora. We used the
+CRAML software to narrow our search for relevant literature. We obtained a corpus of 1,994 pa-
+pers published from 2015-2021 in 5 top empirical management journals (Academy of Management
+Journal, Administrative Science Quarterly, Journal of International Business Studies, Organiza-
+tion Science, and Strategic Management Journal). Within the management literature corpus, we
+searched for papers that could illustrate the use of a method for turning unstructured text into
+data. In Appendix A, we provide additional detail on how CRAML can be used in bibliographic
+research.
+2.1
+Word Counting Approaches (LIWC, CATA)
+Computer-aided text analysis (CATA) and Linguistic Inquiry and Word Count (LIWC) are two
+popular techniques used in the management literature. Experts develop lists of words or dictionar-
+ies that correspond to an overall construct and measure the occurrence of keywords inside specific
+documents [110, 109]. Researchers often use LIWC standard dictionaries to detect common con-
+structs, such as positive / negative sentiment in a corpus of tweets [16]. Using these methods,
+researchers can also develop custom dictionaries to capture previously unstudied phenomena within
+an environment: for example, to measure how actors use specific cultural toolkits in a field of action
+[125]. Such efforts are typically first driven by deduction (keyword selection) and then interrogation
+of text (examining n-grams and short excerpts of text containing keywords) [90].
+We developed keywords deductively (available in Appendix A) and narrowed our search for
+relevant papers using CRAML. CRAML output indicates whether each academic paper in the
+corpus contains keywords that fall within a given construct (or tag): we focused on a subset of 110
+papers that contain reference to text data or a document corpus. Figure 1 shows that text corpus
+analysis and CATA along with it have grown over time; 88 of the 110 papers that mention a text
+corpus also refer to CATA.
+3
+
+Figure 1: Counting Words: The Growth of Management Papers Using Text Data and CATA, AI,
+ML, LDA, NLP
+2.1.1
+Limitations of Keyword-Based Approaches
+Conceptual schemes that rely only on keywords are not very rich [46]. Constructs may not be well-
+captured by word frequency approaches used in CATA and LIWC programs; these methods perform
+less well than ML at tasks such as inferring personality [41]. Word counting assumes that all word
+occurrences equally contribute to the measurement of a construct - that every use of the keyword
+“artificial intelligence” or “machine learning” captures both papers that use an AI or ML method,
+as well as those that study or mention AI and ML phenomena. Because the method relies on exact
+matching and correct spellings, CATA and LIWC will fail to recognize concepts when faced with
+messy data or typos. Without the benefit of context surrounding the keywords, key meaning and
+accuracy are lost to the user. When describing the frequency of terms inside a document, CATA
+methods do not typically adjust for document length, although additional steps can be taken to
+make adjustments [66].
+While keywords can start a search for relevant concepts, rules and qualitative coding pinpoint
+only the relevant text within the documents. Qualitative researchers who seek to inductively build
+theory typically begin by engaging in keyword search, but also engage in qualitative hand coding
+[84].
+2.2
+Unsupervised Learning (Topic Modeling and LDA)
+Text clustering aims to solve the problem of information overload by simplifying a mass of text into a
+smaller number of meaningful categories. While many text clustering methods exist [10], a popular
+technique is topic modeling, which aims to learn “topics” from an unstructured collection of text
+documents. Data is often first heavily pre-processed (stemmed), stripped of common words, and
+converted into a document-term matrix, which leaves only the stems of latent keywords appearing.
+Latent Dirichlet Allocation (LDA) assigns all words in a document to a topic, under the assumption
+that every part of every document contributes to some topic. LDA’s versatility is that it is not
+domain-specific: it can be used to study hacker forums [129], why people retweet [56], online
+communities [18], and discourse on emerging technologies like blockchain [92]. LDA can also assist
+in inductive theorizing [111].
+4
+
+35
+30
+25
+20
+15
+10
+5
+0
+2015
+2016
+2017
+2018
+2019
+2020
+2021
+Text or Document Corpus
+... CATA
+- Proprietary Data or Models
+.Topic Models or LDA
+·ML
+··NLP
+AlOf the 110 text corpus papers in the management literature, 11 papers discuss the use of this
+method, with 5 of these papers appearing in 2021. [36] use LDA to arrive at text-based measures
+of corporate dissimilarity from corporate annual reports, and use 25 crowd-sourced MTurkers to
+ensure themes are reliably identified for the top 25 of 125 latent topics chosen. [58] use LDA on
+annual reports and conduct a semantic network analysis to illustrate the connections and develop
+grounded theories of how firms interact with the legal environment. [73] use patent text to study
+the recombination in breakthrough innovation. [112] study abstracts within a citation network.
+[37] use topic models to analyze CEO text and synthesize analysis of topic models using machine
+learning analysis of CEO facial expressions.
+2.2.1
+Limitation: Meaningless Output
+Latent themes that emerge inductively are meaningless and un-interpretable absent additional data
+(e.g., facial expression analysis to match themes (ibid)), or expert or crowd-sourced judgement.
+LDA assumes that all of the text in every document inside a text corpus is assigned to a theme.
+This is unwarranted if an expert has only a niche interest in a particular phenomenon. Papers we
+reviewed address this concern by limiting the scope of their corpus, or by extensively pre-processing
+to remove potential noise, but this also removes potentially relevant context and data. A second
+assumption of topic modeling approaches is that one must know the number of topics that exist
+within a collection of documents. This is non-trivial, particularly with massive corpora.
+Finally, topic modeling imposes an assumption that a researcher be interested in an “unbiased”
+representation. Experts often disagree about the interpretation of text, and a quest for unbiased
+(as opposed to transparent and replicable) analysis may be misguided [97]. Ultimately, unsuper-
+vised computational methods face difficulty producing meaningful results in the absence of human
+involvement and expert interpretation [95].
+2.3
+The Modern ML Paradigm
+Supervised machine learning (ML) models are widely used in many commercial applications: to
+evaluate candidates for employment [38], to support managers in giving employee feedback [120], to
+moderate text content on the internet, judge the sentiment of customer-written reviews [86], and to
+build proprietary datasets for financial and academic use. Widely available ML methods can train
+a model to learn academic constructs and scale such models over vast volumes of unstructured text.
+However, computational models of text often struggle to provide insights that are interpretable,
+and may be perceived as too difficult for low-resource users to access. Among 10 papers in the
+management corpus discuss ML, and four more that discuss AI, we could not locate any that
+describe the development of a new academic text classification model that is used to construct new
+data from unstructured text.
+While general AI and ML tools rapidly advance, there is a great need for applications in spe-
+cific domains, such as detecting banking fraud [4] or fake websites [3]. “Human-in-the-Loop” or
+hybrid systems are increasingly prominent.1 The idea of human-in-the-loop for AI applications is
+promoted by [130] as a way to introduce responsibility into intelligent agents, as well as to increase
+interpretability. Likewise, human-in-the-loop for ML and NLP is particularly promising, both for
+data preprocessing and model learning [127]. Efforts to use AI and exclude domain experts are
+1Hybrid systems are not novel, with discussions already spanning decades. For example, placing a human in the
+loop was proposed in the design of “socially intelligent agents” [43]. More recently, human involvement in security
+settings [40] and cyber-physical systems [107] have appeared in the computer science literature.
+5
+
+likely to fail, as shown in a study of how AI use in hiring decisions evolved into hybrid practices
+[28]. Many AI systems cannot (and arguably should not) be trained without human oversight, and
+thus such intervention is vital to incorporating the necessary human knowledge into these systems.
+Even with a human-in-the-loop approach, challenges have been noted, for example by [128],
+which among others includes the ability to analyze the impact changes with iterative human in-
+tervention. For academics in management and information systems, incorporating the knowledge
+of domain experts into the process of building structured data is essential for both deductive and
+inductive study. Such domain knowledge is crucial to forming the essence of training data, which
+necessarily represents some aspect of the worldview of a human who chose to train a model from it.
+For supervised ML, challenges lie not so much with the ML methods or models themselves, but
+with the paradigm for ML. The process by which ML models are built (i.e. how information is
+learned) is opaque at the outset. Supervised methods in the Modern ML paradigm, and existing
+tools for the ML pipeline, do not give experts the ability to easily create training data and thus
+train a simple model that can scale over vast quantities of text. As discussed by [7], much of the
+attention around Explainable AI (XAI) has been placed on “the way in which models behave,”
+seeking meaning and interpretability in the outputs of models that can often be highly opaque. If,
+instead, experts could easily build and curate training datasets, there would be greater opportunity
+to build interpretable models accepted by experts and members of the relevant audience.
+Labeled training data is the critical input to supervised ML models to code future, unseen text
+instances. What we call “the Modern ML Paradigm” for supervised learning of text data largely sees
+training data only as input, and holds the interpretability and explainability of ML model outputs
+as a post hoc concern. If building custom training datasets for text were easier, then resulting
+models can be interpreted – and modified – at the input stage. Expert-curated ML models could be
+interpretable and put into action in a domain, and escape some of the limitations of the modern ML
+paradigm: black boxes, proprietary training data, and un-reproducible, meaningless output that
+exclude participation from voices without supercomputers or advanced computer science knowledge.
+2.3.1
+Limitation: The Black Box of Supervised Learning
+The “Black Box” refers to the mystery by which textual inputs are categorized by machines leading
+to certain outputs and are rooted in increasingly large model architectures and consequently, how
+computational models memorize, rather than truly learn. In turn, one is often hard pressed to
+decipher the behavior of a classifier, even with state of the art models – they simply reflect patterns
+observed during training.
+Trust requires understanding “what the machines are doing” [33]. In the modern ML paradigm,
+attempts to “explain the black box” often come after the fact, which [12] calls “Post-hoc Explain-
+ability”. Here, when faced with models that are not interpretable by design, one may try to boost
+explainability after the fact. As [12] writes, post-hoc approaches have become the de facto way of
+achieving some level of explainability with complex DL models.
+Without understanding the data that goes into training the model, the explainability of the
+modern ML paradigm is limited. In a recent survey of explainability in supervised ML methods,
+[30] call for rethinking the problem from first principles, and encourage researchers to ask “What are
+we actually looking for? Do we really need a black box model?” For many experts, the immediate
+answer is no. Even a ML model with a high degree of predictive power is likely to be seen as
+undesirable if it does not produce interpretable results [97, 95].
+Underspecification can result from training models on massive volumes of data and selecting
+the model(s) that achieve a desired predictive power [42]. Underspecification often leads to failure
+6
+
+when those models are used outside of the context in which they were trained. As [69] writes: “the
+process used to build most machine-learning models today cannot tell which models will work in the
+real world and which ones won’t.” [65] calls for greater interaction between humans and machines
+and for explainability when models are faced with new situations – a “sign of mastery.”
+2.3.2
+Limitation: Proprietary Training Data and Methods
+Seen from a different angle, black boxes may be valuable in order to protect trade secrets hidden
+behind such trained models [105]. Secrecy presents risks in the cases where “high-stakes” decisions
+are made by the models in question, having potentially significant societal or economic implications.
+Academic users often rely on commercial data providers that give little to no insight into their
+proprietary process for data creation.
+In our analysis of the management literature, 13 of the
+100 text analysis papers, and 117 papers in total indicate the use of licensed, proprietary data
+or models. The problem identified by [81] is that such computational methods could become the
+“exclusive domain” of private companies and government agencies that operate contrary to the
+academic commitment to openness. The inadequacy of data-sharing paradigms for big data cast
+doubt regarding the veracity of ML models [82].
+Private firms and academics typically advance the state of the art by breaking new records
+for the complexity of data, the size of models, and the number of parameters in a model. Many
+potential contributions from researchers who lack access to super-computing resources, the funds
+to buy large proprietary datasets, or access to confidential government data are excluded [32]. Our
+search for management papers that indicate proprietary data or models illustrate stable trends over
+time, but when big or secret data outputs become the criteria through which the quality of research
+is judged, only those with access can compete, and there may be less attention to “cumulative
+progress toward answering important questions” [44].
+By reducing the need for humans to think, act, or belong (contribute, be included) in the public
+sphere, [72] write that ML systems can constrain and oppress, rather than achieve emancipatory
+goals. To deliver on the potential of ML, improvements needed include greater sharing of data, pro-
+tections for privacy to enable more open data, intellectual property standards to reduce transaction
+costs, and approaches that enable genuine replication [75]. Pre-processing of datasets for supervised
+learning could be a core strength and contribution of social scientists in analyzing text data [45].2
+Despite advances, DiMaggio’s (2015) call for greater systematic research to develop solutions for
+curation challenges and guidelines for pre-analysis and developing training data has largely been
+unmet.
+2.3.3
+Limitation: Meaningful Contributions to Knowledge
+In a statement that rings true almost a decade after it was written, there is little evidence of com-
+putational social science in leading social science field journals [124], or in the management corpus
+reviewed here. Computational social science methods have advanced significantly, but it has yet
+to be demonstrated how computational scientific infrastructure can be applied to important social
+problems [82]. Disciplinary silos, privacy concerns, and unreliable, non-replicable, and proprietary
+2One promising approach is computational grounded theory: a novel framework to use unsupervised machine
+learning to identify patterns, engage a human in interpretive refinement of patterns, and use computational methods
+to assess and confirm identified patterns [95]. This “human-centered computational exploratory analysis” is pro-
+posed to help social scientists benefit from unsupervised computational methods and enhance the transparency and
+reproducability of content analysis [95].
+7
+
+data hamper the potential for computer science methods to provide meaningful insight into society’s
+challenges [82].
+The emergence of a computational social science apart from traditional academic disciplines
+speaks to the hope that ML and AI can advance knowledge. However, the possibilities of these
+technologies are lessened when such tools are perceived as beyond the reach of ordinary users [48].
+Less than a decade old, some such initiatives, such as “data science for good”, have been criticized for
+not giving the social sector “the opportunity to design for what we want” [101]. Without tools that
+enable domain experts to develop their own ML models, there is a risk that new interdisciplinary
+or trans-disciplinary centers might lead to yet another siloed academic discipline as ill equipped to
+solve problems as others [5]. Future opportunities for AI identified by [21] include democratization,
+reducing requirements for data, and enhancing AI explainability and transparency.3
+[122] attributes a “Hyper-Focus” in current ML research to three causes that have led it to
+lose “its connection to problems of import to the larger world of science and society.” First, the
+(over)use of benchmark datasets, many of which are “synthetic”, has “glaring limitations” and still
+make reproducability difficult. Only 1% of ML papers are applied to a specific domain and the
+rest use benchmark datasets.4 By way of contrast, [79] report that 90% of research constructs are
+uncommon, suggesting that using pre-labeled standard benchmark data for training will miss entire
+vast areas of domain-specific knowledge. Secondly, the focus on “abstract metrics” like F-scores
+to determine model quality across domains is a “mirage” that masks the need to focus on impact
+and usefulness of a model. A final issue is the “lack of follow-through,” suggesting that current
+computational research leaves little incentive for connection to sustained research agendas.
+A related concern is the rapidly depreciating relevance of data that many ML models are trained
+on [82]. In the ML training process, models are trained “in the lab” on a training dataset, yet
+the environment in which models are deployed is dynamic. “Big data” research may apply only
+to specific users of a specific portal at a specific time in which a study is conducted [68, 100].
+For that reason, online studies and experiments with large response rates may fail to produce
+reliable or general knowledge [27]. A static training process may simply not reflect the real world
+environment or its rapid evolution [15]. The velocity of internet-based data also creates a limitation
+for computational social scientists’ conclusions [93]. Solutions to these obstacles include forming
+new multi-disciplinary, international journals that permit rapid publication of rigorous quantitative
+descriptions of rapidly evolving phenomena [94].
+2.4
+Seeking Explainable Tools for Social Science
+To sum up the issues described in this section, each method reviewed has strengths, limitations,
+and tradeoffs for experts who seek to analyze unstructured text.
+For domain experts with an
+interest in specific phenomena, the methods reviewed so far do not allow for expert-led, targeted
+extraction of niche constructs hiding within corpora and the construction of standardized data. For
+many qualitative researchers, the systematic analysis and discovery of new patterns within domain-
+specific digitized records is a core contribution – the ability to find the diamond (a single topic)
+in the rough (lots of text). If qualitative hand-coded contributions could be easily scaled, it can
+address some issues found in the supervised ML domain.
+3Emerging paradigms for low-resource Natural Language Processing (NLP) seek to eliminate barriers to accessing
+ML technology [71].
+4Classic examples of these datasets include the Movie Review Dataset [87] or the Yelp Review Dataset. While use
+of standardized datasets may reduce the reproducibility crisis in ML [74], there is a tradeoff. As one might imagine,
+benchmark and standardized datasets have limited application to the real world; furthermore, many benchmark
+datasets are tailored for specific tasks, e.g. movie reviews are often used for sentiment analysis.
+8
+
+3
+Context Rule Assisted Machine Learning (CRAML)
+Enabling experts to create training data for niche classifiers to detect constructs that are relevant
+within a specific domain would address many of the problems identified with the modern ML
+paradigm, and the limitations of unsupervised computations methods. The CRAML method we
+present emphasizes explainability and has a contribution on each of the six dimensions that explain
+the performance of AI systems according to [13]: the models are specific to a single construct, the
+goals are clear, by limiting the chunk size and extracting text from documents in the corpus, the
+training and input data is intended to be context-specific, the output data is interpretable (a 0/1
+binary classification), and the environment is also intended to be domain specific and expert-guided.
+By emphasizing the “human in the loop,” CRAML gives qualitative and quantitative researchers
+control over the training data that is the key input to ML models. This offers new capabilities to
+control the analysis and measurement of phenomena found in massive volumes of unstructured text.
+This section briefly introduces the solution developed and explains how the solution addresses the
+problems described above.
+3.1
+A Framework for Unstructured Text Analysis
+CRAML software gives users the tools to manipulate keywords to extract relevant data from massive
+corpora, create “tags” that seek to capture topics or themes, and subsequently, develop “context
+rule” sets that codify knowledge about the specific pieces of text that correspond to specific tags.
+The CRAML process yields tabular output that matches document-level metadata with a 0/1
+indicator that symbolizes the occurrence of tags in a document [80].
+Figure 2 provides a high-level overview of the CRAML framework. The CRAML process begins
+with the full text of a corpus of documents (Step 0). While metadata is not required, CRAML soft-
+ware is designed to combine characteristics extracted from the text with metadata at the document
+or record ID level.
+In step 1, the researcher chooses keywords to extract from the corpus, and retrieves a “chunk”:
+a block of text containing a user-selected number of words surrounding the keyword. The chunk
+length should contain the full “context window”: all of the relevant context for a human to determine
+if the keyword-containing chunk is relevant or not for some binary classification schema. The user
+can extract all chunks from all of the documents in the corpus, or in low-resource environments,
+can randomly sample from the documents in order to perform Steps 2-4 on a smaller subset.
+In step 2, the researcher analyzes the patterns within the chunks, studying n-grams that reveal
+the most common phrasings surrounding the keyword.
+In step 3, the researcher writes “context rules” that elaborate an ever-more detailed scheme of
+binary classifications of the chunks. We refer to these binary classification schemata as “tags”: each
+tag represents a topic or theme that the researcher defines by recognizing patterns in the extracted
+text and determining if each chunk is (tag=1), or is not (tag=0), illustrative of the tag. There is no
+limit on the number of tags a researcher can define. For each tag, there is no limit to the number
+of rules that can be defined using either exact text matching or regular expressions (RegEx).
+In step 4, the researcher written context rules are applied or “extrapolated” over either the full
+extracted chunks or a sample of the extracted chunks to create a training dataset for ML modeling.
+Extrapolation labels each chunk with a 0 or 1 for each “tag,” or binary classification scheme, and
+creates a dataset that can be used for training ML models. In step 5, common ML algorithms
+use the training dataset to tag the full extracted chunks, and the researcher identifies the best
+performing model. In the final step, the results are aggregated into a document-level database
+9
+
+Figure 2: A Simple View of the CRAML Process
+of structured information: for any document within the text corpus, the researcher knows if the
+document contains a tag. Additional hand-coding by independent third-parties can validate that
+the training dataset extrapolation, and the ML results, are highly accurate.
+Versatile tools for mixed approaches
+CRAML’s pipeline incorporates a novel set of tools that
+provide an end-to-end solution to the challenge of structuring unstructured text data. However,
+researchers may appreciate its flexibility and multiple uses: a researcher may wish to pursue analysis
+using only pieces of the CRAML process. The proposed system is not a rigid algorithm, but rather
+a flexible pipeline of tools created to implement a research framework that was developed to address
+a specific research task. As [99] note, choosing between a dictionary, rules, or supervised machine
+learning involves tradeoffs, and no clear guidelines. In CRAML, particular steps and technologies
+can be interchanged according to the user’s preference, skill set, and research challenge. A qual-
+itative researcher can quickly sample and sift through text data and experiment with alternative
+classification schemes and definitions.5 For another researcher, extraction could be a pre-processing
+step before engaging in a computational grounded theory project that uses unstructured NLP meth-
+ods once the plausibly relevant themes are extracted based upon keywords. A third researcher may
+wish to extrapolate a full dataset without ML. A fourth researcher may wish to only sample a mas-
+sive corpus, extract context windows around keywords, and inductively generate topics or themes
+with extracted text and have no desire to perform further computational avenues of analysis.
+5Emerging paradigms for low-resource Natural Language Processing (NLP) seek to eliminate barriers to accessing
+ML technology [71]. Particularly with low-resource NLP, the availability of labeled data, i.e. text, become crucial.
+10
+
+The CRAML Pipeline, Simplified
+Text Corpora
+Any collection of unstructured text data
+i.e:documents.
+0
+(job postings; legalicontracts; etc.)
+Keywords: 'solicit.hire'. employ'...
+Extractchunkswithkeywords
+Chunks. context window around keyword
+N-grams: common n-sized text chunks, e.g.
+Learn rules with n-gram patterns
+'shall not solicil is a common 3-gram
+2
+Tag a sample via rules to create
+Using expert-created rules, label documents witha
+3
+training data
+matching: identify qualifierwords (e.g: negation)
+Using the training data created in step 3,
+Learn ML models
+train Ml models, ie binary text classifiers
+4
+Create
+Classify the entirety of the text corpus, i.e. label all documents with the
+given tag(s): The result is a structured, relational database where each
+5
+Database
+entry corresponds to a document from the original corpus.3.2
+A Bridge to Solving Real-World Problems
+By positioning context rules as the crucial bridge between domain expert knowledge and structured
+datasets that represent embodied knowledge, CRAML provides a “traceability” from datasets clas-
+sified by ML models back to the context rules that lead to them – and the humans who wrote
+those. By placing a focus on explainability at the first bridge from unstructured data to structured
+data(sets), the second bridge from training data to trained models becomes easier to cross. ML
+modeling “presumes a world of already existing (divine or rationalistic) rules, which only need to
+be formalised, in order to make sense to a machine (or an analytical philosopher for this reason)”
+[11]. Context rules in CRAML codify which text belongs to which topic or theme according to the
+user. To the extent such rules can be articulated consistently, then they can be extrapolated over
+unstructured text to create fully structured datasets to train ML models.
+Rather than presuming unbiased training data, CRAML extends the user’s worldview to the
+realm of ML models via expert-created context rules. Interpretive frameworks lend meaning to
+text and are a cornerstone of academic research. Scaling methods such as coding and grounded
+theory over large volumes of text contributes to theory development [117]. Rigorous manual content
+analysis by qualitatitve social scientists is often geared toward the induction of topics and themes,
+yielding new constructs, analytical frameworks, or mid-level theory of some phenomenon [59].6
+Alternatively, a quantitative or hypothesis-driven researcher might pursue evidence of a phenomena
+within a text corpus, quantify its frequency, and then analyze it.
+In CRAML, the use of context rule sets serves as the foundation for representing the knowledge
+of a domain expert, without the need for explicitly annotating all unseen instances (i.e. documents).
+Through the extrapolation process, the hybrid CRAML framework requires manual work only in
+the crucial first stages, and leaves the remainder to automation. CRAML’s initial step is similar
+to processes used in IS research: for example, to develop a specialized ontology of hypotheses,
+[85] couple rule-based approaches for extraction and word embeddings. The “human in the loop”
+contributes transparent manual codifications of text, which allow for the replicable and configurable
+construction of tabular datasets used either immediately for quantitative social science analysis, or
+to train ML models.7 Because CRAML involves human expertise and gives control over training
+data to the user, the ML model that results from CRAML is interpretable as a product of a human-
+built and curated rule set that can be published, and then contested, examined, and modified by
+others. This mitigates concerns over black box ML models.
+CRAML built models can have real-world applicability, because training data and ML-built
+datasets can be formed by domain experts who largely address Wagstaff’s (2012) concerns regarding
+abstract metrics and lack of follow through. Empowering users to create novel, meaningful datasets
+and ML models in their worldview also enables rapid changes that can be put into action locally.
+This comes at a time where novel ML or DL approaches can be severely limited by available datasets,
+with no widely accepted approach to create novel ones as needed and in an efficient manner.
+As a final response to the challenges introduced in the previous section, CRAML’s methodologi-
+cal transparency is intended to address several of the problems with proprietary data and otherwise
+6For scientific purposes, inductively derived analytical frameworks from text should be a) intra-subjectively
+reliable, b) inter-subjectively reliable, and c) fully reproducible [95]. This means that a single person should reach
+the same coding conclusion again and again, a second person should reach the same conclusion, and the methods,
+data, and analysis should be transparent enough to permit replication.
+7Explainable and interpretable models can be built when users “steer learning” through feedback and interaction
+[65]. [7] writes that “explainability can only happen through interaction between human and machine.” Of course,
+the creation of such hybrid system requires expert human labor. [105] writes that “[i]nterpretable models can entail
+significant effort to construct, in terms of both computation and domain expertise.”
+11
+
+unreachable methods.
+With a standard desktop computer and open source software, CRAML
+enables interactive engagement with massive text corpora without prior programming knowledge
+(although users will find some programming knowledge helpful and advanced users may seek to
+customize the underlying code for niche purposes). At each crucial step of the framework, CRAML
+saves and shows the user the underlying data in CSV format in order to enable the interactivity es-
+sential to truly achieving a “human in the loop” and records each step of the process for replication
+and transparency purposes.
+By making the framework as open and transparent as possible, and publishing the code base
+and the underlying data used here, we provide opportunities for users to test, harness, or modify
+the framework. CRAML software is available under a under a Creative Commons Attribution-
+NonCommercial-ShareAlike 4.0 International License. The artifacts created and used by CRAML
+in the intermediate stages are extracts and samples of the plausibly relevant text from a document
+and document corpus using keywords and context windows. A user can control what information
+is extracted from the corpus, and thus remove sensitive data. Thus, CRAML can mitigate some
+privacy protection and sensitive information concerns that limit access to sensitive data. Other
+researchers working with big data have taken a similar approach by extracting only relevant pieces
+of larger documents [113]. By
+3.3
+An Application of CRAML: Job Advertisement Text
+Job seekers face difficulties finding the right jobs, and employers face frictions in job search that
+represent additional recruitment costs. Search frictions harm both workers and employers by in-
+creasing the barriers to good matches in the labor market, and reducing competition for labor
+[29, 89]. A suite of ML classifiers that added niche filters to job search engines could benefit job-
+seekers, employers, and workforce agencies. With support from the National Science Foundation,
+the National Labor Exchange created the NLx Research Hub in 2021 to “increase the amount of
+actionable labor market information in the U.S. to facilitate the recruitment, hiring, and training
+opportunities of American workers” and “deepen partnerships between industry, government, and
+academia by enhancing the infrastructure to support the convergence of research, education, and
+talent pipelines.”
+Workers who desire more flexible, remote jobs after COVID-19, disabled workers seeking specific
+working conditions, union workers, workers with a professional license, and veterans as well as
+veteran’s spouses may all be underserved even while being preferred by specific employers.
+An
+employer can gain a competitive advantage by hiring workers who are otherwise discriminated
+against, but only in an efficient and competitive labor market [19]. Job seekers may easily become
+discouraged without information on whether, for example: a job is located near public transit,
+or whether an employer will interview an ex-felon, a teen, or a non-resident on a visa. If some
+employers seek to target and hire underserved audiences, but job ads never reach the workers, then
+research should aim to reliably identify which jobs might be especially relevant for a particular
+worker.
+Research application
+CRAML was first developed using job advertisement text data to support
+research on the labor market. While the underlying text is confidential and licensed, we describe and
+release rules files and nine ML classifiers that achieved a high accuracy in detecting job characteris-
+tics and barriers to employment under a Creative Commons Attribution-NonCommercial-ShareAlike
+4.0 International License. The research implications of this work are not only immediate research
+papers, but a potential to release custom-built ML classifiers and create open tools for real-time
+12
+
+information systems that track changes in the labor market. Such application could improve both
+research and contribute to reducing barriers to employment in job advertisements. Ultimately, bet-
+ter data on employment practices obtained from job advertisement text and other sources of text
+information could have a profound impact on research capabilities in this field.8
+In Appendix B, we provide a list of tags and the keywords extracted as part of an effort to
+identify specific barriers to employment, the accuracy of the models built, and discuss how the
+broader labor market research community can contribute to this effort.
+4
+A Step-by-Step, Replicable No Poach Classifier
+We demonstrate the start-to-finish CRAML approach by applying it to an empirical context where
+the resulting analysis might be meaningful, transparent, and replicable. Toward this end, we con-
+tribute a new text corpus of 151,708 franchise documents, and the cleaned and pre-processed text
+we used in this analysis. We publish metadata that tracks which of 12,992 records a particular
+document corresponds to, and includes the effective date, company name, and unique ID. We also
+publish the rule sets that are the manual hand-coded input, enabling replication and scrutiny of
+the results. We also publish the training dataset and the ML model.9
+4.1
+Empirical and Data Context
+“No poach” clauses in contracts are also referred to as collusive pacts or anti-competitive restraints
+on employee mobility, and have drawn interest from academics, regulators, and policy-makers.
+While anti-competitive language is contained in public documents, sometimes contrary to public
+policy, these documents are inaccessible for many: available only in massive, unsearchable collections
+of PDF documents on state agency websites. With subtle variations in language and no guide about
+where to look for these clauses, no poach clauses are diamonds in the rough: a few sentences in
+hundreds of thousands of documents with millions of pages. Indeed, such clauses were largely not
+known to exist by the relevant academic and policy community of interest until the release of a 2017
+working paper published as [77]. The paper contained a limited sample and relied on a third party
+data provider to identify no poach clauses. Following the release of the working paper, eleven state
+attorneys general issued a letter in 2018 demanding the practice end, many franchises voluntarily
+ended the practice, and the State of Washington in 2018 first negotiated settlements with franchise
+companies in which many removed their no poach clauses.10.
+Both no poach and non-compete clauses are known to place downward pressure on wages [31,
+17]. Given their importance in reducing opportunities for job mobility, there is great interest in
+descriptive statistics regarding the prevalence of these clauses. Overcoming the inaccessibility of
+the text within public documents was a significant challenge. We assembled a large collection of
+Franchise Disclosure Documents (FDDs) from the state of California by scraping PDF documents
+8In ongoing work supported by the Russell Sage Foundation Future of Work Program and NLX, a job-
+advertisement level SQL database built from CRAML’s classifiers using NLX data is now operational and new
+classifiers are under construction.
+9The PDFs are hosted in partnership with DocumentCloud, and will be released upon publication. On Doc-
+umentCloud, where they can now be searched, discussed, and annotated. Additional items will be uploaded to a
+scholarly repository upon publication.
+10See Washington State Attorney General Report, Letter from State Attorneys General. As Ashenfelter wrote,
+“it is instructive that the mere revelation of collusive agreements, whether legal or not, has so quickly provoked a
+strong response from both the antitrust authorities and the franchisors whose agreements contained these no-poach
+clauses” (qtd. in [77])
+13
+
+from the public web. These records exclude companies that may be exempt from filing, and may
+be missing observations due to limitations when accessing data from the web.11
+In addition, we make available the machine-readable text corpus we build from the downloaded
+PDFs and the metadata that ties documents to specific company filings. For pre-processing, we used
+Python’s Tika, and for files that could not be initially read with this, we used ABBYY Fine Reader.
+For the California corpus, we assembled 151,708 documents in 6.99 GB of cleaned machine-readable
+text that can be traced back to a total of 12,992 franchise records. We consider the record to be
+the unique ID that the state assigns to multiple documents from a franchise on a particular date.
+We trace each document back to a record with metadata that includes the name of the franchise,
+and the date of the filing.
+4.2
+The Construction of Training Data
+4.2.1
+Step 1: Extract Relevant Text to Reduce Information Overload
+Figure 3: First process in the CRAML Framework – Extract Data
+The extraction process encompasses taking the unstructured text files and preparing a cleaned
+dataset of only the text that is plausibly relevant that is ready for hand-coding. By reducing the size
+of the text files being worked with, and delimiting the extracts to the relevant text in the corpus,
+this step addresses challenges of computational resource intensity, and assists in sifting for relevant
+information in a large corpus. This is a manual, iterative process – a loop that is exited when
+11While we were able to obtain and match the 151,708 documents to the 12,992 records via web scraping, we
+identified 16,216 franchise disclosure records from January 2013-July 2022, and are investigating additional methods
+to acquire any missing data, which we believe to be randomly distributed.
+14
+
+1.Extract Data to Reduce Information Overload
+ProblemsAddressed:
+Siftingforrelevantdata
+Chunkextraction with expert guidance on classification
+Resource-intensivecomputation
+schema (tags),keywords,and contextwindowlength
+Irrelevantdataintextcorpus
+Enter witha
+Expert creates
+text corpus
+keywordsand
+tags
+Tags,keywords,
+Expertexplores
+Expert selects
+andcontextwindowsize
+No
+text_ex.py
+contextwindows
+finalized?
+n-gramsand
+Input:textchunks
+adjustskeywords
+(N)fortext
+Output:n-grams
+andtags
+chunks
+Yes
+extract.py
+Input:textcorpus,
+Runtext
+Sampleorfull
+keywords,tags,
+explorationtool
+corpusextract?
+windows size (N)
+(text_ex.py)
+Exitto
+Output:stored
+Extract chunks
+2.Build Rules
+chunksincsvfiles
+fromcorpus
+(extract.py)the user is satisfied that all of the relevant text is extracted from the corpus. Figure 3 illustrates
+the extraction process, which corresponds to Step 1 outlined in Figure 2. Two main software tools
+(extract.py and text_ex.py) aid the user in finding and exploring the relevant text.
+We chose initial keywords “hire”, “recruit”, “employ”, and “solicit” to explore if franchise doc-
+uments contain a no poach clause. The initial keywords chosen suggested additional ideas for tags,
+which in turn, suggested new ideas for keywords. To aid in this process, a repeated N-gram ex-
+ploration helped discover the contexts in which given keywords appear the most. This exploration
+prioritizes the extract, suggest new ideas for keywords, tags, rules, context windows. Because the full
+context was important to explore initially, the earliest exploratory extracts focused on the 20 words
+surrounding each keyword. Following all of the processes described below, a final context window
+of 13 words was selected (6 words to the left and right of the keyword). The goal when removing
+irrelevant or non-essential information is to reduce noise and build a highly focused ML classifi-
+cation model. In an iterative and flexible process, more keywords were subsequently added: for
+example, “poach”, “non compet”, “noncompet”, “covenant” and “not to compete” simply restarted
+the process.
+4.2.2
+Step 2:
+From Rule Sets to (Training) Data via Extrapolation, Testing, and
+Validation
+After the extraction process, an expert conceptualizes and defines the desired classifications, or
+tags, and builds a rule set for each tag in a manual and iterative fashion. Figure 4 details the
+iterative process of Step 2 in Figure 2 that involves validation, extrapolation, and the refinement of
+rule sets. This process concludes when the expert is satisfied that the extrapolated rules are valid
+on a sample of the text. The rule set is then “extrapolated” to the full extract from the corpus,
+yielding a structured dataset of accurately classified chunks – a training dataset, in other words.
+As described in the following section, the results of Step 2 can be used immediately for descriptive
+research regarding the contents of documents, or as a basis for training ML models.
+The cycle begins with the initial creation of rule sets for each tag, which can be done manually
+by an individual researcher, or team of researchers. Constructing and designing accurate indicators
+requires researcher familiarity with ontological subtleties and appropriate construct validation and
+scale development methodology [126, 88]. Rules are written in a CSV file that contains a list of
+rules, the priority level of each rule, and the corresponding tag, assigned a 0 or 1. As earlier, the
+N-Gram tool may be helpful – doing this prioritizes the creation of rules that will “cover” the largest
+parts of the entire data. Priority level determines the order in which a rule is run. A earlier rule
+can be over-written by a subsequent priority rule.
+Step 2 then involves the use of rule sets and the extrapolation algorithm (extrapolate.py) to
+validate the rules. In essence, the extrapolation process will convert the set of rules into an extended
+dataset, and will tag each chunk according to the user’s encoding of each rule.
+The resulting
+dataset contains the unique document identifier, the extracted chunk matching a certain rule, and
+the defined encoding for this chunk.
+Note that this extrapolation is done individually for each
+rule set and tag, thus resulting in a training dataset for each rule set (file). A second software
+tool (validate.py) relates to the validation of the data that is the output of extrapolation. Once
+extrapolated, the expert tests the performance of the rules against actual chunks that are coded by
+those rules. The expert can export a strategic sample of chunks meant to ensure each rule is valid –
+choosing a random sample of N examples per rule. This enables independent hand-coders to score
+each chunk, which can then be re-imported to assess accuracy and performance of the rules.
+For the franchise document data, allowing iterative exploration of keywords and adjustments to
+15
+
+Figure 4: Second process in the CRAML Framework – Build Rules
+rules, we developed a set of over 500 rules and 6 tags to classify suspect anti-competitive clauses
+in the corpus. We first focused on finding all employee “no poach” clauses. As one rule for the no
+poach tag states: “you may not seek to employ or retain any employee or independent contractor
+who is at any time employed by us.” When examining similar extracted chunks, we found that many
+documents also contained language that went further than prohibiting an employer from soliciting
+another party’s employee, but also prohibited an employer from hiring or employing. We create
+a separate tag these “no hire” clauses. Such “no hire” clauses, as in the following example from
+the no hire rule set, state that: “party shall not hire or solicit to hire any person employed then or
+within the preceding year by the other party.”
+Independent validation in which a third researcher hand-coded 706 chunks indicates an initial
+91% match between an independent third party and the extrapolation of rules, suggesting a high
+degree of inter-rater reliability in ability to detect characteristics of no poach clauses. While our
+emphasis here is to ensure that there is strong inter-rater reliability between the CRAML user
+and an independent observer in this test example, we do not claim perfect identification of all no
+poach clauses. For a regulator, additional scrutiny would be required, but the overarching goal
+is to identify plausibly relevant and/or problematic no poach language. The pipeline enables any
+observer to classify the documents according to any arbitrary schema. We emphasize that CRAML
+here enables content validation processes at the input stage to ML. Independent assessments of
+reliability are key to any conclusions.
+Step 2 Results: A Labeled, Structured Dataset for Analysis
+Step 2 yields a dataset for
+training a ML classification model, or, if the underlying corpus is small enough (as is the case
+here), the rules can be applied to the entire dataset and reveal which filings contain which clauses
+16
+
+2.BuildRuleSetsto ClassifyText Chunks
+ProblemsAddressed:
+Scalingclassificationschemes
+Expert-ledrulesetconstruction,extrapolationto a sample
+Buildingrepresentativetraining
+trainingsetorfull dataset,andvalidationofresults
+datafromunstructuredtext
+Enterfrom1.
+Expertwrites aset of
+with chunks,
+rulesfor eachtag and
+tags,keywords,
+determinestheirpriority
+andn-grams
+w.r.ttextchunks
+Expertis
+(Independent)
+No
+satisfiedwithrules
+validation?
+expertshand-code
+extrapolate.py
+Text exploration tool
+Validationset
+Input: rule set(s),
+yieldsfrequenttext
+extractedtext
+patterns
+Output:structured
+training data
+Yes
+validation.py
+Validate rules
+Training data
+Input:training data
+withselected
+orfull dataset
+Output:selected
+sampleof data
+needed?
+Exitto
+sample,validation
+3.ML
+metrics
+Extrapolate rule seton
+Classification
+textchunksto create
+representative.dataset
+(extrapolate.py)according to the specified rules.
+4.2.3
+Step 3: Training ML Classifiers to Build Structured Datasets
+While the above analysis is based on an extrapolation of rules to all chunks in the dataset, CRAML
+yields data that a ML classifier can train. Although many algorithms exists for such a training
+process, the CRAML framework trains a binary classifier for each tag. In other words, each training
+dataset is created from a rules file, which contains one or more tags. Accordingly, each classifier
+can be traced back to a rule set to perform a 0/1 classification for the tags included therein. The
+training process is described in greater detail in Appendix C.
+Once the classifier(s) are trained, they can be deployed to classify the original data, i.e. the entire
+unstructured text corpus, or can be used on other sources of data. This represents the completion of
+the CRAML framework, as one can now build a structured, labeled dataset from the unstructured
+text of a document corpus using a ML model. This entire final process is illustrated in Figure 5.
+Figure 5: Third process in the CRAML Framework – Train Classifiers
+4.3
+Evaluating the Model
+In this empirical context, we train a no poach classifier built with training data from California. We
+use the classifier to build datasets for both California, in order to obtain a comparison between the
+rules-based approach and the ML approach using the same data. The “no poach” classifier is built
+with training data from a 10% sample plus all of the no poach tag=1 observations in the full sample.
+In some cases, when the occurrence of positive or negative tags is very low, manual augmentations
+to training data such as this are required in order to receive acceptable model performance. We
+obtain an accuracy score of 0.99, precision of 0.97, recall of 0.96, and an overall F1-Score of 0.97.
+17
+
+3.TrainMachine Learning Classification Models
+ProblemsAddressed:
+ComplexityofMLtechniques
+Learningrobust,generalizableclassifiersbuiltuponthe
+Availabilityoftraining data
+expert-validatedtrainingdata
+Creationofstructureddata
+Enterfrom2.
+with validated
+training data for
+ExpertselectsaMe
+eachruleset
+methodfromanarrayof
+availablechoices
+Model
+Mergeandstore
+data (i.e.to OB)
+Learnmodelon
+Newrulesornew
+training data
+model?
+Rules
+Returnto2.
+BuildRules
+Expertsatisfied
+Finish
+No
+with.metrics?
+YesThe harmonic mean of precision and recall (or F1-score) is based upon a comparison between the
+ML output and the training dataset. A common statistic in ML, with a maximum score of 1 when
+precision and recall are perfect, and 0 when either precision or recall is zero, the F1 score suggests
+a high level of accuracy and recall between the training dataset and results.
+Figure 6 displays the percent of all rule-detected and ML-detected no poach clauses in the
+California Corpus within each year for each record filed from years 2013-2022 (with partial data
+for 2022). The pattern depicted with the California data is similar to the rule-based analysis. It
+shows that from 2015-2017 over 60% of the records contained no poach clauses, after which there
+was a decline until the percent stabilizes below 40%. This suggests that the interventions that
+followed [77] had a large effect to decrease the prevalence of anti-competitive no poach language
+in franchise documents.
+The continued prevalence of these clauses, despite interventions from
+authorities, requires further investigation (in another paper): while the no poach clauses continue
+to exist, inspection of the text chunks reveals that while some remain the same as before the
+intervention of the Washington State Attorney General, while others now limit their applicability to
+more favorable jurisdictions and others restrict their application to highly compensated employees.
+Figure 6: Analysis of Suspect No Poach Clauses in California Franchise Documents
+Practical Note on Model Accuracy
+One noteworthy aspect of CRAML is that the above
+statistics reflect performance of the model at the “chunk” level.
+If an expert were looking to
+confirm that certain documents contain no poach clauses, the record is the level of analysis where
+they would want to begin their search.
+Given over 150,000 documents stored in nearly 13,000
+18
+
+.7
+.6
+.5
+.4
+.3
+.2
+.1
+0
+2012
+2014
+2016
+2018
+2020
+2022
+RuleDectectedNoPoachClauses
+--MLModelDetectedNoPoachClausesrecords, this could be a daunting task. Moving to the level of the records, in California, the no
+poach classifier closely matches the rule-generated results, with only 22 false negatives and 672 false
+positives in 12,922 records. Thus, at the record level, ML model achieves a 0.95 F1-score, 0.996
+recall, 0.91 precision, and accuracy of 0.946.
+Further, an inspection of text chunks reveals that a significant portion of the false positives
+are in fact related to other language that accompanies no poach clauses and belong properly in
+the context of anti-competitive language in these documents: jurisdictional restrictions on no poach
+clauses, language that applies no poach clauses only to specific employees, and language that creates
+non-compete clauses. Precision at the level of the record would be 0.04 higher (0.95) if one considers
+these clauses to be relevant to a search for a broader construct of anti-competitive language. The
+results of CRAML are fully traceable to choices made in the construction of a rule set for the no
+poach classifier. As seen in Figure 6, the ML classifier identifies more suspected no poach clauses
+then the rules, and this increases in 2021. Additional research using this corpus is pinpointing
+fine-grained characteristics of language in these documents that restrict employee mobility.
+A final note: if one were dissatisfied with the model performance and sought one with higher
+recall or lower accuracy, or a more or less specific definition of the no poach construct, it would
+possible to “steer learning” and achieve a desired result by changing rule sets and thus re-shaping
+the training data. If desired, a user could add or remove all jurisdiction, narrow, and non-compete
+language from the no poach rule set in order to achieve a more discriminating classifier. A user
+could also combine all of the rules to make a single classifier that memorizes a larger pattern related
+to all types of anti-competitive language that appear in the documents.
+5
+Discussion
+The CRAML framework makes several contributions. First, the framework enables the systematic
+and structured process of creating novel datasets from unstructured text corpora. Second, the result
+harmonizes advanced, automated information extraction and ML techniques with the input and
+expertise from manual analysis performed by supervising researchers. The exploration and iterative
+process performed during the context rule creation stage involves work that is not only difficult
+to perform automatically, but also that will arguably never come close to matching the diversity
+and expertise of human experts with domain knowledge. As a result, this intermediate stage in the
+framework incorporates a human element that is lacking in modern classification frameworks.
+5.1
+Future Directions
+5.1.1
+Technical Improvements
+Future research directions regarding the technical backbone of the CRAML framework should aim
+to bolster the extrapolation stage of the pipeline.
+Embeddings can be utilized to improve the
+transformation of context rules to datasets. With embeddings added to the extrapolation method,
+the need for training a ML classifier in the end may become obsolete.
+A second area of future work involves building up tools to aid the domain expert in the initial,
+manual-driven stages of the CRAML process. Keyword extraction, topic modeling, automatic rule
+induction, and knowledge graphs could all be useful tools to support the domain expert express his
+or her worldview, as well as explore large text corpora in a richer way.
+Although the focus is currently placed on ML techniques, the role of more advanced classifiers
+remains an open area of investigation. Deep Learning, in particular sequential models, could prove to
+19
+
+be powerful in boosting the predictive capability of models trained on CRAML-generated datasets.
+Of course, this would come with the added overhead of extra training and parameter tuning, which
+must also be taken into account for future endeavors.
+5.1.2
+Computational Social Science
+CRAML is designed with flexibility and web-based sources of text in mind. A plug-in was created
+to integrate DocumentCloud (used by journalists and academics to post government documents)
+for the project related to no poach agreements. New plug-ins could draw data from web-based
+sources of text such as Twitter. Niche ML classifiers built from user-data in a specific domain could
+address content moderation challenges at scale [57, 62]. To address a concern in [101], government,
+civil society, and non-governmental organizations could develop context rule sets to capture text
+that is relevant to their interests and publish or license ML classifiers that provide useful feeds
+and classifications of information tracking on topics of societal concern. For academics, editors and
+reviewers could demand greater transparency when claims are made about data built form text.
+Concerns with proprietary data sources and privacy can be partially addressed by the infor-
+mation extraction methods used here. While additional efforts are needed, including the potential
+development of further tools for differential privacy with text, the extraction process is a step to-
+ward efforts to protect individuals against identification and protect the data owner from violation
+of proprietary information and trade secrets. For example, researchers have been barred from ac-
+cessing records due to privacy and confidentiality concerns, but with careful selection of keywords,
+analysts could code chunks of extracted text and classify every document in a corpus without ever
+accessing the full or confidential information.12
+Finally, researchers in the humanities and social scientists can hopefully develop diverse and
+practical applications that uncover constructs and patterns currently “hidden” in unstructured
+text. The CRAML framework and software tools can be used to analyze text in any language. To
+the extent a construct is intra-subjectively reliable, it could be developed by a researcher into rules
+and scaled over vast amounts of unstructured text. To the extent that inter-subjective variance is
+high, we hope that by decreasing the time and effort needed to scale a framework, there will be many
+opportunities for diverse voices to produce contesting interpretative schemes that are transparent
+and replicable.
+12For example, researchers could use CRAML software to track the 20th Century use of residential restrictive
+covenants that barred Black, Jewish, Asian and other ethnic groups from living in certain neighborhoods. County
+commissioners of deeds have either barred researchers or severely limited access to digitized records due to concerns.
+For one project focused on Hennepin County, see https://mappingprejudice.umn.edu/.
+20
+
+Acknowledgements
+We are grateful for support from the Economic Security Project Anti-Monopoly Fund; Loyola Rule
+of Law Institute; Loyola Quinlan School of Business; and Loyola University Chicago. All errors are
+the authors’.
+Conflict of interest
+The authors have no conflicts of interest.
+Supporting Information
+See our Github repository for the full code base: https://github.com/sjmeis/CRAML_Beta.
+21
+
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+
+A
+Appendix A: Using CRAML for a Literature Review
+Bibliographic research often begins with search for relevant papers using an academic search engine,
+but such search has a difficult time retrieving only the papers that use a specific empirical method
+or type of data, for example. To find papers that illustrate the challenges CRAML was created to
+address, we analyzed a corpus of all published papers from 5 top management journals from 2015-
+2021 (Academy of Management Journal, Administrative Science Quarterly, Journal of International
+Business Studies, Organization Science, and Strategic Management Journal). We first assembled
+the corpus and PDFs in Zotero, and then exported the metadata. We converted all PDFs from
+these journals to text, minimally cleaned the text (lower case, removing punctuation, replaced
+abbreviations), and used CRAML software to find relevant papers using keywords, tags, and rules.
+We deductively generated list of tags and keywords. The keywords.json file contians the tags
+and keywords used to extract all keyword-containing chunks of text. The context window was set
+to 6 words, yielding chunks of text of a maximum length of 13 words. After retrieving 13 word
+chunks, we examined n-grams in CRAML and developed rules files for each tag in order to classify
+the chunks that were relevant to our search. The following headings present the rules files used
+to classify which papers in the management literature contain relevant concepts - keywords alone
+generated numerous false positives. We note that this effort could be much further refined. Given
+the small size of the corpus and the variety of tags, machine learning was not desirable or attempted.
+CRAML was highly useful to iteratively narrowing a search for relevant literature, and we stopped
+when the results produced the relevant papers. As seen in the notes on the rule sets, keyword based
+approaches alone are insufficient to narrowing accurately, and researchers can benefit from a process
+of refinement that is context-aware and rule-based.
+A.1
+“Is Text” rules: Papers drawing from Text Corpora
+These rules that define the tag istext or “is text” identify papers that refer to a text corpus or
+text data. In the first priority of rule-based classification, chunks containing the keywords “text”,
+“repository”, “corpus”, and “document” are initially coded 0 (not istext). The subsequent rule at
+priority level 1 classifies all chunks containing the exact matching text (e.g. “text analyis”) 1 (is
+istext). Given the istext rules, the resulting metadata will report the papers that discuss text data
+and corpora equal to 1 for istext. The most relevant papers were found when combining the istext
+tag with additional tags described below.
+33
+
+Rule
+Prio
+istext
+text
+0
+0
+repository
+0
+0
+corpus
+0
+0
+document
+0
+0
+text analysis
+1
+1
+text corpus
+1
+1
+textual corpus
+1
+1
+text mine
+1
+1
+text mining
+1
+1
+prepared text
+1
+1
+text based analys
+1
+1
+text data
+1
+1
+Figure 7: istext Rules
+A.2
+ML rules
+To find papers that discuss supervised learning, we construct the simple ML tag. To make Figure
+1, we focus only on observations where istext and ML are both equal to 1.
+Rule
+Prio
+ML
+learning
+0
+0
+supervised learning
+1
+1
+machine learning
+1
+1
+deep learning
+1
+1
+Figure 8: ML Rules
+A.3
+NLP Rules
+We follow the same structure for the NLP tag for finding papers that use NLP. For NLP, we also
+use regular expressions to find any chunk containing mention of the term “embedding” and one or
+more of “word”, “text”, or “language.”
+Rule
+Prio
+NLP
+nlp
+0
+1
+natural language process
+0
+1
+REGEX :::(? = .∗\bembedding\b)((? = .∗\bword\b)|(? = .∗\btext\b)|(? = .∗\blanguage\b)).∗
+1
+1
+Figure 9: NLP Rules
+A.4
+Proprietary rules
+The keywords for proprietary data and models and the proprietary tag extracted a large number
+of irrelevant chunks. To limit the focus to non-transparency in data and models, we use regular
+expressions to combine our base priority keywords with the added terms “data” or “model” to
+capture the papers that use or refer to proprietary data or models.
+34
+
+Rule
+Prio
+proprietary
+confidential
+0
+0
+license
+0
+0
+sensitive
+0
+0
+proprietary
+0
+0
+secret
+0
+0
+REGEX :::(? = .∗\bdata\b)((? = .∗\bconfidential\b)|(? = .∗\blicense)|(? = .∗\bsensitive)|(? = .∗\bproprietary\b)|(? = .∗\bsecret)).∗
+1
+1
+REGEX :::(? = .∗\bmodel\b)((? = .∗\bconfidential\b)|(? = .∗\blicense)|(? = .∗\bsensitive)|(? = .∗\bproprietary\b)|(? = .∗\bsecret)).∗
+1
+1
+Figure 10: Proprietary Rules
+A.5
+Topic Modeling Rules
+For the topic modeling tag topic_model, we look for papers with chunks of text that refer to
+unsupervised learning, Latent Dirichlet Allocation (LDA), and topic models.
+Rule
+Prio
+topic_model
+unsupervised
+0
+0
+unsupervised learning
+1
+1
+lda
+1
+1
+topic model
+1
+1
+latent dirichlet allocation
+1
+1
+Figure 11: Topic Model Rules
+A.6
+AI Rules
+For the tag AI, we look for papers with chunks of text that refer to artificial intelligence.
+Rule
+Prio
+AI
+artificial
+0
+0
+ai
+1
+1
+artificially intelligen
+1
+1
+artificial intelligen
+1
+1
+neural network
+1
+1
+Figure 12: AI Rules
+A.7
+The Results
+CRAML’s extrapolate function yields a CSV file. Each row is a paper, and each column contains
+the metadata attributes of the paper (authors year, etc.) and each tag constructed in CRAML.
+For each paper, CRAML provides a 0/1 indicator of whether or not the paper contains a chunk
+corresponding to the rules files above. Here, we present a table that aggregates the result of the
+CRAML analysis by year and theme:
+Because we are interested in particular in papers that use text corpora, to make the graph in
+Figure 1 and conduct our literature review, we filtered the metadata for only the papers that equal
+1 for istext. CRAML allowed us to find “needles” in a “haystack” of publications, narrowing our
+search of the literature, allowing us to more closely examine the plausibly relevant papers, and read
+and incorporate relevant papers into our literature review. The data for Figure 1 that highlights
+the discussion of various text analysis techniques within these papers is presented below:
+35
+
+Year
+Proprietary
+Data
+or
+Models
+Topic
+Models
+or
+LDA
+ML
+NLP
+AI
+CATA
+Text or
+Docu-
+ment
+Corpus
+2015
+19
+2
+0
+1
+0
+53
+7
+2016
+11
+0
+1
+0
+0
+68
+10
+2017
+18
+0
+0
+0
+2
+69
+9
+2018
+20
+2
+0
+2
+2
+73
+17
+2019
+13
+3
+2
+1
+3
+82
+18
+2020
+17
+2
+2
+1
+1
+67
+18
+2021
+19
+6
+7
+3
+2
+80
+31
+Table 1: Total Papers by Year that Reflect Rule Sets
+Year
+Proprietary
+Data
+or
+Models
+Topic
+Models
+or
+LDA
+ML
+NLP
+AI
+CATA
+Text or
+Docu-
+ment
+Corpus
+2015
+1
+2
+0
+1
+0
+6
+7
+2016
+2
+0
+1
+0
+0
+8
+10
+2017
+0
+0
+0
+0
+0
+6
+9
+2018
+1
+1
+0
+1
+1
+11
+17
+2019
+3
+2
+1
+1
+1
+10
+18
+2020
+2
+1
+2
+0
+1
+13
+18
+2021
+4
+5
+6
+3
+1
+19
+31
+Table 2: Subset of Papers Where istext=1 by Year
+36
+
+B
+Appendix B: Using CRAML to Build Classifiers from
+Job Advertisement Text
+One advantage of CRAML is that a classifier can be trained and validated using proprietary infor-
+mation but can be made available to other academic researchers for transparency, validation, and
+replication while preserving underlying proprietary information. To illustrate, we describe and pub-
+lish nine classifiers from job advertisement text and outline our process for building and validating
+these. We describe a process for building open source research datasets drawn from proprietary text
+data with transparent rules and discuss a growing research ecosystem to develop useful classifiers
+drawn from the text of job advertisements.
+B.1
+Building and Publishing New Classifiers from Job Ad Text
+Below, we describe the construction and performance of classifiers already constructed using job
+advertisement text data. The following variables are constructed from a random forest ML algorithm
+that classifies each job advertisement 0/1 on a particular variable. These variables are otherwise
+coded 0, but are equal to 1 if the job advertisement indicates:
+• Work From Home. A job with the opportunity to work-from-home, including both full-time
+and hybrid work-from-home jobs.
+• Independent Contractor. A 1099 independent contractor job.
+• Professional License Required. A job requiring a professional license or formal apprenticeship.
+• Union Presence. A job within a collective bargaining unit or a job that involves negotiating
+and working with unions (labor relations jobs, e.g.).
+• Citizenship Required. A job where the holder must be a U.S. citizen.
+• Work Authorization Required. A job where the job holder must be legally authorized to work
+in the U.S.
+• Visa Inclusivity. A job for which a firm is willing to sponsor a visa-holder for the position.
+• Visa Exclusivity. A job for which a firm is not willing to sponsor a visa-holder for the position.
+• EOE/AA Statement. A job ad that contains EOE/AA statement is present.
+In building each classifier, close attention was paid to building reliable and valid measures. To
+construct each variable listed above, the 6 words before and after every appearance of a “keyword”
+(in column 2) of Table 3 were extracted from the text corpus of job advertisements.
+Research assistants and one lead researcher hand-coded a sample of the most frequently occurring
+13-word “text chunks” 0 or 1 for each variable we wanted in the finished dataset. Based upon the
+hand-coded sample, context rules were initially drafted. Table 4 illustrates the hand-coding and
+manual validation process. For the work from home variable, independent hand-coding generated
+1,524 increasingly lengthy context rules. Following extrapolation to a training dataset drawn from
+a random sample, RAs performed an additional round of independent hand-coding to arrive at
+a total of 2,901 hand-coded chunks for the work from home variable that are matched to the
+training dataset. Comparing known “true positives” via hand-coding and known “true negatives”
+37
+
+1. Variable
+2. Keyword(s)
+Work From Home
+“home", “remote", “telecommut", “telework", “virtual", “videocon-
+ferenc", “internet", “anywhere"
+Independent Contractor
+“contract”
+Professional
+License
+Re-
+quired
+“licens", “credential", “certifi", “apprentice"
+Union Presence
+“collective", “bargain", “contract", “union"
+Government Contractor
+“affirmative", “opportunity", “eoe", “contract"
+Citizenship Required
+“citizen”
+Work
+Authorization
+Re-
+quired
+“authoriz”
+Visa Inclusive
+“visa”, “1b”
+Visa Exclusive
+“visa”, “1b”
+Table 3: Keywords for Initial Classifiers Built
+1. Variable
+2. Hand-coded Chunks
+3. ML Sample N Matched
+with Hand-Coding
+Work From Home
+2,901
+15,297
+Independent Contractor
+1,287
+8,771
+Professional
+License
+Re-
+quired
+11,107
+15,665
+Union Presence
+5,357
+14,254
+Government Contractor
+1,427
+19,564
+Citizenship Required
+418
+242
+Work
+Authorization
+Re-
+quired
+890
+1,888
+Visa Inclusive
+6,796
+3,660
+Visa Exclusive
+6,764
+1,613
+Table 4: Hand-coding and Matched ML Sample for Initial Classifiers Built
+from hand-coding to the training dataset, we are confident that the training dataset classifies at
+least 15,297 work from home chunks correctly. Because the process begins by feeding the training
+dataset all chunks containing the keywords, most chunks in the training dataset are equal to 0,
+and include many chunks containing irrelevant uses of the word “home”: “homework tutor”, “home
+healthcare”, and “homeland security”, e.g., all contain the keyword “home” after processing. This
+“negative sampling” of chunks is crucial for training ML models to distinguish between a 0 and 1.
+Because the focus is accuracy, or correctly identifying work from home jobs with a 1, it is possible
+that recall suffers, as this process misses isolated instances of work from home jobs with highly
+unusual text patterns.
+Once a strategic sample of the training dataset provides a perfect match with the hand-coded
+data, we use the training dataset to train a ML model that predicts, e.g., if a given job is work-
+from-home. We tested logistic regression, naïve Bayes, and random forest models, and found that
+random forests perform best. Table 5 presents the size of a strategically selected sample of ML
+results used to assess accuracy. This sample size varies for each variable, as each variable occurs
+38
+
+1. Variable
+2.
+% of ML Sample Con-
+firmed True Positives
+3. F1 Score
+Work From Home
+92.1%
+0.976
+Independent Contractor
+98.4%
+0.994
+Professional
+License
+Re-
+quired
+74.5%
+0.890
+Union Presence
+67.4%
+0.874
+Government Contractor
+39.6%
+0.996
+Citizenship Required
+69.4%
+0.976
+Work
+Authorization
+Re-
+quired
+97%
+0.994
+Visa Inclusive
+80.6%
+0.890
+Visa Exclusive
+76.0%
+0.874
+Table 5: Percent of True Positives Confirmed by Hand-Matching and F-1 Scores
+with different frequency in the raw data, and while initially drawn from a random sample of chunks
+containing the keywords, it is not random, but oversamples the most frequently occurring “positive”
+chunks.
+Sample size needed to validate varies by the complexity of the rules needed to capture variation
+in the chunks that contain the keywords. For some variables, a large sample is necessary because of
+subtle variations in the text: there are many ways to indicate a “work from home” job, and as such,
+there are many keywords and many different types of chunks that contain the keyword. In complex
+cases, a domain expert must elaborate many rules to capture the variation in the text. For other
+variables, such as “citizenship required,” among chunks containing the keyword “citizen,” there is
+little variation in the text and only 63 context rules are required to handle the classification scheme
+envisioned. A smaller sample is acceptable in such cases because the frequency of key chunks in the
+sample of chunks are relatively large: correctly classifying the chunk “citizenship is required” 1 and
+almost everything else in the sample 0 captures most of the nuance. A very high proportion of the
+percentages in Column 2 of Table 5 not known to be true positives are true negatives.
+The percent of known true positives in column 2 of Table 5 is based upon exact matches between
+hand-coded chunks and the results of a sample of ML tagged chunks. Finally, to assess the accuracy
+of the ML algorithm, column 3 reports the F-1 score.
+While “work from home” is an omnibus measure of whether a job-holder can work from home,
+we earlier abandoned work on potential refinements such as hybrid work field jobs that permit work
+from home. Each step in this process has the potential for mistakes to slip into the classification
+process. While the ultimate validity rests on the opinion of other experts, the hand-coded files, the
+software, and large samples of text chunks can be published to encourage others’ efforts. The data
+and software transparency will allow others to make their own models following their own process
+and could lead to better classifications.
+In the process described above, we paid additional attention to qualifiers: words that have the
+ability to change the meaning of a text chunk in a significant manner. Keep words are just that –
+words that should be kept, even though they exist in a region to be trimmed away.
+39
+
+B.1.1
+Building Open Source Datasets
+The framework adopted and the CRAML software tool facilitates a pipeline for storing all (merged)
+classification output to a database of choice. In this particular application with the data mentioned
+here, a simple relational SQLite database with the following schema was used.
+id INTEGER PRIMARY KEY
+year INTEGER
+month INTEGER
+soc REAL
+onet REAL
+employer TEXT
+sector REAL
+fips TEXT
+title TEXT
+Figure 13: Example Database Schema (for Jobs)
+Using this schema, a jobs database was created where the novel, complete, merged, and classified
+dataset is stored. An example snippet of this database’s contents is shown in Figure 14.
+id
+vendor
+effective-date
+nopoach
+app-7653
+DHH Group Inc.
+3/24/2017
+1
+app-15957
+Apogee Learning LLC
+9/20/2019
+1
+app-1853
+The Agency Real Estate Franchising LLC
+4/3/2015
+1
+app-7888
+Winmark Corporation (Once Upon A Child)
+3/28/2017
+1
+app-18366
+Atomium Inc.
+6/25/2020
+1
+app-23189
+Vision Source LLC
+3/11/2022
+0
+app-22302
+Brinker International Payroll Company L P (Chili’s)
+11/1/2021
+0
+468744
+Annex Brands Inc.
+1/17/2013
+0
+app-14481
+Gokhale Method Institute Inc.
+4/11/2019
+1
+app-14643
+Pizza Guys Franchises Inc.
+7/22/2019
+0
+Figure 14: Random Sample from Jobs Database
+Note that much of the data from the meta-data was left out for readability and for anonymiza-
+tion.
+The tag names have also been abbreviated, but they follow the same order as listed in
+Section B.1. In essence, these tag columns represent the codification of the original text data into
+a structured dataset. This dataset, in turn, can be used for further research and analysis.
+B.2
+Growing an Ecosystem for Labor Market Research from Text
+The pipeline outlined above regarding the ML models and rule sets we released can be scaled
+and other researchers can build their own text to data classifiers of job advertisements.
+NLx
+Research Hub data is proprietary and licensed to academic users for academic use, as well as
+state workforce agencies for research purposes. Access to the full corpus of job advertisements and
+the associated metadata requires an application and compliance with a (free) licensing agreement
+in order to protect sensitive information.
+However, releasing de-identified extracts of keyword-
+containing chunks of the text of job ads could be both fair use and encourage a community of
+40
+
+academic researchers and citizens to develop ML classifiers. Such text chunks, and not the full
+corpus, are all that is needed to build a niche classifier. The process of constructing a ML classifier
+could be done entirely in CRAML without ever needing access to sensitive information.
+Once built, if licensed for non-commercial academic use, scholars who obtain permission to access
+the underlying full text can use ML classifiers on the full text corpus and produce new open-source
+research datasets. Certain forms of data aggregation pose little risk: for example, occupation, state,
+commuting zone, and yearly summary data. With respect to firm-level data, aggregation is possible
+when exercising judgement to ensure no recent sensitive matters are publicly released (e.g. recent
+recruitment efforts that indicate adoption of a particular business strategy that might affect market
+valuation or competitors’ strategy).
+41
+
+C
+Appendix C: The CRAML Pipeline
+This appendix describes the CRAML methodology in detail with illustrations from the worked
+example introduced in Section 4.
+C.1
+Extraction Algorithm
+In Algorithm 1, we present the algorithm to extract context windows from a set of text documents,
+i.e. a corpus. This represents the important first step for handling large-scale unstructured text
+corpora by first extracting the “candidate diamonds” from the rough, in order to allow for the
+precise analysis of a domain expert.
+Algorithm 1 Extraction Algorithm
+Require: Text: collection of text documents, Keywords: list of defined keywords
+Ensure: list of extracted files (location)
+1: all_contexts = {}
+2: for raw_text in documents do
+⊲ Note: done in parallel (unordered)
+3:
+contexts = []
+4:
+id = generate id
+5:
+if any keyword in text then
+6:
+cleaned = clean(text)
+⊲ text replace and regex cleaning
+7:
+for sentence in cleaned do
+8:
+if any keyword in sentence then
+9:
+c = get_context(sentence)
+⊲ get context window
+10:
+contexts.append(c)
+11:
+contexts = set(contexts)
+12:
+all_contexts[id] = contexts
+13: df = pd.DataFrame(all_contexts)
+14: df.to_csv()
+15: return list of saved filenames
+C.2
+Keywords
+As displayed in Algorithm 1, a list of defined keywords is required for extraction. The extraction
+algorithm will extract any chunk of text where one of the keywords appears, and store the chunk
+and metadata about its location in the corpus inside a CSV file for human analysis. Users must
+define a list of keywords for each tag, which are given further elaboration in Section C.5.
+Note that the extraction algorithm pulls all chunks where keywords are exact matched to a
+string of text. For example, the keyword “employ” will extract all of the variants that contain that
+exact keyword (employment, employer, employee, unemployment, etc.).
+C.3
+The Output
+The result of running Algorithm 1 is a CSV formatted dataset containing chunks of text, with
+a minimum of two fields: id and text.
+Note that additional fields may also be included.
+The
+ID matches the identification number from the original data, and text represents a delimited list
+42
+
+of context windows around extracted keywords.
+In this case, a context window with a defined
+parameter n refers the an extracted chunk of text with a maximum of n words to the right and left
+of the keyword. If a punctuation mark is reached before n, then the context window will be shorter.
+Thus, with a n of 12, context windows are a maximum of 25 word chunks. Context windows can
+be selected as either words or sentences; ie, a user can extract all keyword-containing sentences and
+the n sentences to the left and right of a keyword. A sample from one extracted CSV file in Table
+6 illustrates this, with firm names changed:
+id
+firm
+text
+10D4977B-000
+Acme Inc. 1
+{you shall not hire or permit ...}
+ADSPO15-0807
+Acme Inc. 2
+{will not hire an applicant...}
+CHR21009-CHS
+Acme Inc. 3
+{a contractor shall not employ ....}
+99999-001
+Acme Inc. 4
+{non solicitation agreements with ...}
+Table 6: Illustrative extracted context windows with fictional company names
+Note that for display purposes, only outputs relatively short in length were chosen. It is often
+the case that the extracted “text” is much longer in length, i.e. many contexts are extracted per
+contract. The output of the extract algorithm is an “intermediate” dataset of (ID, text) tuples,
+where the text is simply a long, ’|’ delimited string of all the extracted context windows. Looking
+at the example shown, one can see that in each extracted chunk of text, a keyword is present, along
+with its extracted context.
+C.4
+N-gram Exploration
+The first step towards building up rule sets is having all of the plausibly relevant text extracted.
+The exploration of n-gram structures within the extracted data ensures that the context window is
+correct, and if so, serves as a first step for construction of rules described in the following section.
+This is accomplished with the algorithm presented in Algorithm 2. The result with a given n is
+the a file with the enumerated occurrences of each relevant n-gram, sorted in descending order.
+Algorithm 2 N-gram Exploration
+Require: Parent Directory: where the extracted CSVs are located, n: desired n-gram size
+Ensure: file with enumerated n-grams
+1: global_counts = {}
+2: for file in parent directory do
+3:
+for row text in file do
+4:
+split = text.split(’|’)
+5:
+for chunk in split do
+6:
+length = len(chunk.split())
+7:
+rules = chunk.split()[max(0, length/2 - n), min(length, length/2 + n)]
+8:
+global_counts.update(Counter(rules))
+9: return global_counts.to_csv()
+43
+
+C.5
+Rule Creation: Building the Bridge
+From the previous step, a researcher is now enabled to obtain a general picture of what context
+windows appear with the unstructured text data, as well as their relative occurrences. Using this,
+the researcher follows two decision processes: (1) the creation of a tag set, and subsequently (2) the
+creation of a rule set for each tag. Both sets are defined below.
+Tags
+A tag is a title given to a certain characteristic of a particular document. These tags can be
+easily and simply defined, and are binary in nature, i.e. 1 if true or 0 if not true. The collection of
+defined tags make up the tag set. Each tag in the tag set is assigned either 1 or 0 for every unique
+document (i.e. unique ID) in the original data. Specifically for the franchise document example,
+the following tag is defined:
+• nopoach – a non-solicitation clause that prohibits one franchise from recruiting workers from
+the another franchise.
+With this framework, one can define an arbitrary amount of tags; furthermore, exactly what
+these tags mean, ie. what definition they take on, is entirely up to the researcher. Binary classifi-
+cations can be further broken down by defining additional “sub-tags”. As demonstrated below, an
+examination of the context surrounding non-solicitation suggests further tags for future research.
+At the data analysis stage, these can be combined to create new measurements of concepts involving
+multiple tags. Crucially, the meaning that is assumed by each tag is defined via its rule set, which
+is discussed next.
+• nopoach_nohire – a no poach clause that includes a no hire clause.
+• noncompete – an employee non-compete clause.
+• jurisdiction – language that limits the application of a no poach or non-compete to certain
+jurisdictions.
+• narrow – language that limits the application of a no poach or non-compete to certain em-
+ployees.
+• no_nopoach – language that limits the use of no poach or non-compete clauses - stating that
+these clauses are not enforceable against employees.
+Rules
+For each given tag, a researcher will now define a list of rules that encompasses the definition
+and characteristics of this tag. More concretely, a rule is a chunk of any number of words. Therefore,
+a rule can be a single word, or even an entire sentence (up to the maximum length of the extracted
+chunks, here 25). A single rule set, defined within a corresponding file, can contain one or more
+tags. If more than one tag is contained within a rule set, this means that the tags that are bundled
+together are related enough such that some rules more overlap, or some rules may define one tag,
+while precluding the other. For each tag contained within a rule set, this tag is defined for each
+given rule, i.e. is assigned either 1 or 0. Finally, every rule in all rule sets must be assigned a
+priority (“prio”), which indicates its relative order of operation compared to other rules within the
+same rule set. An example excerpt from a rule file is given in Table 7.
+Priority is important in the sense that it defines a hierarchy of how text chunks might be
+assigned certain tags. From the above example, one starts with every chunk containing “hire” to
+be nopoach=0 at prio=0. When, however, one encounters “may not hire” within a piece of text,
+this then is a plausible indicator that nopoach=1. If a text chunk contains “may not hire” – the
+44
+
+rule
+prio
+nopoach
+hire
+0
+0
+shall not hire
+1
+1
+will not hire
+1
+1
+may not hire
+1
+1
+you shall not hire or permit any third party or outside vendors to access or perform any service
+2
+0
+may not hire an applicant who has a felony
+2
+0
+will not hire any person regardless of medical marijuana card
+2
+0
+shall not hire or promote anyone who may have contact with residents
+2
+0
+not hire offer to hire or otherwise solicit any employee
+3
+1
+Table 7: Excerpt from the rule set of the nopoach tag in formative stages
+subsequent rule “may not hire” assigned priority prio=1 proceeds to classify it with nopoach=1.
+Upon examination, that rule turns out to have exceptions. Moving on to a higher priority rule,
+prio=2 can create exceptions to prio=1 rules: for example, with prio=2, a rule that states “may
+not hire an applicant who has a felony” overwrites the previous tag allocation, now assigning text
+chunks containing the string of text in the rule to nopoach=0. In this way, priority is important to
+handling iterative coding work and possibly overlapping or contradicting rules.
+The final important aspect of rule creation comes with the use of Regular Expressions, denoted
+by rules with the “REGEX:::” qualifier prepended to the regular expression itself. Instead of simple
+text matching for a rule, regex rules will instead check to verify if a particular text chunk satisfies
+the regular expression or not. Their usage allows for generalization, in situations where contexts
+are variable in length and content, yet possess the same general meaning.
+Once the researcher feels that the rule set is saturated, it is important to “prune” rules and
+validate them through repeated extrapolation and adjustment.
+Context windows should be no
+longer than the longest rule, which should be no longer than necessary to precisely capture the tag.
+The final rule sets used in the franchise document analysis are available online.
+C.6
+Extrapolation: Crossing the Bridge
+With this collection of rule sets (for all defined tags) in hand, a tool is now needed to translate the
+rules contained within to a workable dataset. Such a tool is useful because it takes the manually
+coded context rules as input, and it then proceeds to “extrapolate” them into a training dataset
+from either a selected subset of extracted data files or the full dataset. Thus, we can cross the bridge
+from expert-created rules to structured, annotated datasets.
+The Subset
+As mentioned, the extrapolation algorithm can operate on a selected subset of the
+entirety of the data, so as to create a representative training set, from which a robust, accurate
+classifier can be trained. This is accomplished by randomly and uniformly selecting documents
+from the original text files. In the case where a model will not be learned, i.e. where only the
+extrapolated dataset is desired, performing this sampling is not necessary.
+The Extrapolation Algorithm
+The algorithm used to create a training data set for each tag
+is now defined. Note that this algorithm is run per tag, meaning that the eventual output is a
+training set for each tag, which will then be used to train a classifier for each tag. The algorithm
+pseudocode is outlined in Algorithm 3.
+45
+
+Algorithm 3 Extrapolation Algorithm
+Require: Parent Directory: where the subset CSV files are located, Rules File: a rule set for
+a given tag or tags, s: sampling rate, do_neg: whether to perform negative sampling
+Ensure: training data set for given tag(s)
+1: results = []
+2: for file f in subset do
+3:
+data = read_csv(f).sample(s)
+⊲ sample desired fraction of data
+4:
+for text in data do
+⊲ each ’|’ delimted extracted line
+5:
+for rule r in rule set do
+6:
+match = []
+7:
+plus = 0
+⊲ for negative sampling only
+8:
+for x in text.split(’|’) do
+9:
+if ’REGEX’ in r then
+10:
+if regex.search(r, x) then
+11:
+match.append((x,1))
+12:
+plus += 1
+13:
+else if plus > 0 and do_neg == True then
+14:
+if not any ru in x for ru in rule set then
+15:
+match.append((x,0))
+16:
+plus -= len(tags)
+⊲ i.e. number of tags in rule set
+17:
+else
+18:
+if r in x then
+19:
+match.append((x,1))
+20:
+plus += 1
+21:
+else if plus > 0 and do_neg == True then
+22:
+if not any ru in x for ru in rule set then
+23:
+match.append((x,0))
+24:
+plus -= len(tags)
+25:
+random.shuffle(match)
+26:
+for m in match do
+⊲ m[0] = text, m[1] = negative sample?
+27:
+results.append(text chunk, rule, priority-weighted length, tag encoding)
+28: training = DataFrame(results)
+29: training = training.sort(priority-weighted length).drop_duplicates(chunk)
+30: return training as CSV
+One important note about the extraction algorithm is the sampling rate. Since many files are
+included in the subset, running extrapolation on the entirety of this subset would result in quite
+large training datasets. To avoid this, only a random sampling of each subset file is taken, in order
+to ensure a manageable training dataset. Secondly, the concept of negative sampling is incorporated
+into the algorithm. Such a concept allows for “negative”, non-keyword containing text chunks also
+to be included in the training data, in the case that a classifier that can discriminate between
+keyword- and non-keyword-containing instances is desired.
+Ultimately, the main purpose of the extrapolation algorithm is to bridge the human-centric rule
+creation phase with the ensuing model training and classification stage. Concretely, the manually
+created rule sets that are the product of the former are converted to large, yet workable training
+data sets that are vital to the functioning of the latter. Thus, this transition from defined rule sets
+46
+
+to classifier training is facilitated by such an extrapolation method.
+As described above, a user may need to augment the training data produced from CRAML in
+order to improve model performance. Poorly performing models may reflect that the underlying
+tags are not well-defined, and need additional refinement, or simply that there are not enough
+positive or negative cases in the corpus to build a reliable classification model.
+C.7
+Baseline Testing Cycle: Boosting Real-World Applicability
+After an initial extrapolation, the expert engages in iterative testing to revise the rules to achieve
+a comprehensive and accurately coded dataset. The expert does this with output from the extrap-
+olation. An excerpt (shortened for readability) of the nopoach rules is provided in Table 8.
+id
+chunk
+rule
+nopoach
+527557
+shall not recruit or hire any employee or former employee offranchisor or any
+shall not recruit
+1
+781133
+of offenders page of monitoring center staff vendors shall not employ felons in
+shall not employ felons
+0
+272571
+in item ahove you may not solicit customers from outside your territory without
+may not solicit customers
+0
+487216
+or our designee you will not hire third party or outside vendors to
+you will not hire third party or outside vendors
+0
+792020
+franchise lyou may not recruit or hire any employee or former employee of
+may not recruit
+1
+714298
+non solicitation of employees employee agrees that during
+non solicitation of employees
+1
+Table 8: Some entries from the novel training data created for nopoach during testing
+As can be seen, the extrapolated training data files contain the extracted text chunks, which
+rule “caught” the particular chunk, and finally the appropriate tag value. This file can be reviewed
+by the user to determine if the rules are working as intended. A sample of chunks that oversamples
+positive tags (=1) and provides a minimum number of cases per rule can also be sent at this point
+for blind review by third-party coders to validate and ensure inter-subject reliability.
+In the Table 8 example, early rules such as “shall not recruit”, “shall not employ”, and “shall
+not hire” were later abandoned due to the multiple exceptions to these rules as seen in the Table.
+Instead, discrete statements that clearly stated that an employee shall not be recruited or solicited
+or hired were tagged nopoach=1
+C.8
+Validation: Involving Third-Party Independent Coders
+Validation helps to ensure inter-rater reliability, accuracy, and precision. Involving third-parties at
+the stage at which rule sets are producing seemingly reliable results tests whether the tags are well-
+enough defined to be agreed to by third parties. The researcher gives an independent coder only
+a description of the desired tag, the text chunks, and deletes the rules and the CRAML-generated
+coding. The independent coder completes their review, and the researcher compares the results
+of the rule-set produced coding with the independent coder’s coding. All discrepancies should be
+reconciled before proceeding further.
+Based upon the performance displayed by this last step in the process, or by an externally
+imposed requirement to repeat the process, the researcher can choose to revisit the tags and rule
+sets, once again performing an exploration to search for more representative rules. It is important
+to emphasize the necessity of judgement in this phase, as the decision to repeat this process is
+a subjective one. Incorporating hand-coding by independent research assistants can help greatly.
+Moreover, the encoding, i.e. tag values, given to each particular rule must come from knowledgeable,
+grounded reasoning, especially in cases where certain keywords serve different meanings in possibly
+very disparate contexts. Therefore, it is in this cycle where the most manual effort is required, but
+also where the crucial foundation to the rest of the framework is built.
+47
+
+C.9
+Model Training and Classification: Datasets in Action
+The final stage in the proposed framework is the classification itself, i.e. the mapping of a particular
+text chunk to its corresponding tag set encoding (0/1 for each tag). In order to accomplish this,
+classification models must be learned from the rule sets discussed in the previous section. This
+process is now outlined.
+The presence of context rules alone are not sufficient in the sense that they represent high
+precision classification rules that will always detect exactly what is described by the rules. The
+next step of using a classifier is to learn a model that not only detects these “simple” cases that can
+be caught by string matching or regular expressions, but rather one that can also learn in which
+general contexts keywords appear which cause a certain tag to be true. This, therefore, motivates
+the need for comprehensive training data.
+The final step in the testing cycle involves the training of a baseline classifier to test the per-
+formance of this classifier on an unseen test set. In this case, a simple Naive Bayes classifier was
+chosen. First, training instances are converted to TF-IDF vectors (introduced in more detail later),
+and then a Naive Bayes classifier is trained for each tag. Finally, output metrics are displayed,
+namely Accuracy, Precision, Recall, and F1. Using these metrics, a researcher can (roughly) evalu-
+ate the current performance of the classifier, which indicates the strength (“representativeness”) of
+the underlying training data, i.e. rules.
+C.9.1
+Flexibility in Machine Learning Methods
+An important step towards the building of a general-purpose classification system was model selec-
+tion. In particular, it becomes the task to identify the Machine Learning method best suited for
+the multi-label, binary classification task at hand. Crucial to note is this multi-label aspect, as it is
+certainly possible for a single document to have more than one tag attribute be present. As such,
+multiple candidates for classification models were chosen, all of which could handle this multi-label
+binary classification task. So far, only “shallow” Machine Learning models were tested.
+The methods included:
+• Naive Bayes – also used as the baseline classification method. Simple probabilistic classifiers
+using Bayes’ theorem as a backbone. Relatively easy and efficient to train.
+• Logistic Regression – classification technique utilizing the logistic function (and a classifi-
+cation threshold) to predict the value of a dependent variable.
+• Stochastic Gradient Descent Classification – a misnomer in the sense that SGD does
+not actually perform the classification. Rather, SGD is used to optimize a linear model, in
+this case a Support Vector Machine.
+• Random Forest – a classifier using an ensemble of Decision Trees.
+In a test of the various methods on a sample classification task (for the nopoach tag), the
+classifiers performed as described in Table 9.
+In the case of large text corpora, particular in the example of no poach clauses in state contracts,
+it may be the case that the positive cases, i.e. where a tag is assigned 1, are in the minority. As a
+result, the accuracy score becomes somewhat less important. More meaningful are the precision and
+recall scores. Essentially, precision measures the percentage of correctly identified positive cases,
+i.e. how many of the classified ’1’s are indeed truly positive cases. Recall measures that percentage
+of correctly identified positive cases among all positive cases in the true labels. Together, these two
+metrics can be succinctly summarized in the F1-score, which is the harmonic mean of the two.
+48
+
+Acc.
+Precision
+Recall
+F1
+Naive Bayes
+0.93
+0.60
+0.95
+0.74
+Logistic Regression
+0.99
+0.91
+0.96
+0.94
+SGD SVM
+0.98
+0.91
+0.92
+0.92
+Random Forest
+0.99
+0.97
+0.96
+0.97
+Table 9: Performance of various ML classifiers
+As can be observed from Table 9, the Random Forest model shows superior performance with
+regards to all metrics. The same outcome was observed across the board with various rule sets,
+or rather their corresponding training data. As a result, the Random Forest was chosen to be the
+classification method of choice for the purposes of this dataset.
+With the respect to the general-purpose nature of this text classification framework, it is impor-
+tant to emphasize that the choice of classification method here will not necessarily be the optimal
+choice for other applications. In addition to this, the utilization of more advanced and powerful
+methods could certainly prove to be beneficial, and this remains a topic for future research. In
+the end, though, the framework allows for essentially any model to be used, as long as it can be
+properly stored and loaded for use in the process pipeline.
+As part of the CRAML framework, the task of choosing a specific model is left to the user. This
+make sense due to the fact that different data, different domains, and different desired outcomes
+may require different models to be chosen. In the end, the focus of CRAML on the data creation
+process allows for a flexibility in the choice of model to train on this data. Further details on this
+process can be found in the CRAML documentation.
+C.9.2
+Outline of Model Training
+In order to adapt the use of classification models such as Random Forests for the classification of
+novel text datasets such as the one described throughout the previous sections, some considerations
+must be made. They are described below.
+TF-IDF is utilized to convert a database of unstructured text entities into a matrix of numerically-
+valued vectors. Concretely, for a dataset containing n documents and a vocabulary of m words, the
+resulting TF-IDF matrix is n x m in dimension. Through this vectorization of text, models can be
+trained and classification can now be performed.
+As a point for future work, the utilization of more advanced (and potentially meaningful) text
+representations could lead to richer training data for the proposed CRAML framework.
+Training - Grid Search
+With the training of ML models comes many tuneable parameters. In
+order to optimize the resulting classifier for each tag, a tuning stage was added into the framework,
+which determines the optimal parameters, e.g. for a Random Forest, given a particular dataset.
+Here it is important to emphasize the significance of this stage in the overall framework. As all
+potential incoming datasets may be different in nature, different parameter values may be needed
+to achieve the best performance possible. In order to best support the general-purpose nature of
+the proposed framework, performing fine-tuning of parameters is crucial.
+Training - Purification
+As a final step to creating the classifiers for each tag, a purification
+process was run on the trained models, in order to reduce size, and as a result, classification time.
+This was accomplished via an available library, which eliminates unneeded dependencies and in the
+49
+
+case of Random Forests, prunes the trees according to certain criteria. The effects of this process
+were quite dramatic, reducing most models to at least half the size. The potential complexity of
+Random Forests, and thus the need for the purification process, is visualized in Figure 15, which
+display a pre-purification decision tree.
+Figure 15: One of the decisions trees within the nopoach Random Forest
+C.9.3
+Classifier Integration
+Once a model for each tag is trained, it is then stored in pickle format, so that it can be later loaded
+and utilized within the framework. To do this, the user must manually enter the filename of each
+saved model into a JSON formatted file, which maps each tag to its corresponding classifier.
+50
+
+丰Note how these tags match up with the mapping of tags to manually defined keywords. The
+naming convention used for the saved models was to specify the method used, the tag to be classified,
+the achieved F1-score, and the use of purification or not.
+A significant decision that was made along the design process of the framework was whether
+to utilize the negative sampling scheme that was left as an option in the extrapolation process
+(Algorithm 3). This decision would most directly affect the function of the classifiers. More con-
+cretely, without negative sampling, the classifier for each tag would be to “classify a tag as 0 or 1,
+provided that the chunk to be classified contains a tag-defined keyword”. On the other hand, per-
+forming the the negative sampling process introduces random, non-keyword-containing text chunks
+into the model training process, thereby learning these instances into the given model. Here, the
+classification task becomes “classify any given piece of text as 0 or 1, regardless of its content”.
+With these two approaches in mind, it was ultimately decided to implement the former, thereby
+only advancing a text chunk to the classification stage if it indeed contained a keyword. If not,
+the classification was automatically made to be 0. It is quite important to stress that this design
+decision was made knowing the makeup of the textual data, as well as the characteristics of the
+tags to be classified. In the end, in order for a tag to be assigned a 1, a necessary condition is for
+it to contain a tag-specific keyword. Otherwise, it is not possible to obtain the classification of 1.
+The classification process, therefore, is in place to “weed out” keyword-containing text chunks that
+actually do not lead to the desired tag attribute. In other domains, i.e. with other text datasets
+created via this framework, this line of reasoning may not hold absolutely, and an argument could
+be made for the use of negative sampling. In this way, it is once again paramount for (a team of)
+researchers to define their tags thoroughly and explore the makeup of the underlying data.
+One final component is the option of a preprocessing step for each classifier. The motivation
+is that in the text chunks, which are relatively large in length compared to the single keyword
+within, there might exist much information, i.e. words, that do not play a role in a particular tag
+at hand. Particularly with tags in which the pertinent information sits close to the keyword, any
+other irrelevant information will only serve to confuse the learning of a classification model. With
+this in mind, the proposed preprocessing step will serve to “trim” the left and right ends of a given
+text chunk, thus reducing the amount of text noise within this chunk. In this process, though, two
+considerations must be made. Firstly, if certain qualifier words, such as negations, exists within
+the regions to be trimmed, this could potentially be vital information lost. Secondly, there may be
+specific known words or phrases that appear that usually appear in the proximity of a keyword,
+yet might also be trimmed away. For these reasons, two more mappings, following the structure of
+previous ones where an entry exists for each tag, are defined. Qualifiers involves the words that
+have the ability to change the meaning of a text chunk in a signficant manner. Keep words are just
+that – words that should be kept, even though they exist in a region to be trimmed away.
+With these definitions and the preprocessing steps, the pseudocode is outlined in Algorithm 4.
+In the testing with this preprocessing stage, the TRIM parameter was chosen to be 2, resulting
+in chunks of length 5, not including possibly kept words. In the end, this stage was excluded from
+the framework in the context of the job posting data, for with many tags there was actually an
+observed decline in classification performance. This sheds light on the importance of relatively
+faraway context words from the main keyword for many of the tags. Again, this may differ with
+other datasets, so testing with this preprocessing stage is recommended.
+51
+
+Algorithm 4 Preprocessing Algorithm
+Require: Training CSV: file that contains the training data to be trimmed, Tags: tags to be
+processed, Qualifiers: for each tag, Keeps: for each tag, TRIM: target context size
+Ensure: trimmed training data
+1: new_data = []
+2: for text in training data do
+3:
+index = get_index(text)
+⊲ get index of keyword within chunk
+4:
+for q in Qualifiers do
+5:
+found = search_for(q, text)
+⊲ find qualifiers in chunk
+6:
+if found then
+7:
+text = qual_prepend(found, text) ⊲ prepend all found qualifiers to words in chunk
+8:
+lower = max(0, index - TRIM)
+9:
+upper = min(len(text), index + TRIM)
+10:
+new_text = text.split()[lower:upper]
+11:
+keep = []
+12:
+for k in Keeps do
+13:
+if k in text then keep.append(k)
+14:
+new_text = keep + new_text
+15:
+new_data.append(new_text)
+16: return new_data
+C.10
+Storing
+The final process in the framework is to consolidate the classification results, merging them with
+the original data to be stored for later retrieval and analysis.
+The framework facilitates for the storing of all classification outputs to a database of choice. In
+this particular application with the data mentioned here, a simple relational SQLite database with
+the schema in Figure 16 was used.
+id TEXT PRIMARY KEY
+vendor TEXT
+effective-date DATE
+type TEXT
+text TEXT
+Figure 16: Example Database Schema (for nopoach)
+Using this schema, a nopoach database was created where the novel, complete, and classified
+dataset could be stored. An example excerpt of this database’s contents is shown in Figure 17.
+Note that some of the meta-data, including the text, was left out for readability. In addition,
+we mask the firm name here in order to avoid drawing attention to the specific detail as opposed to
+the results of the process. In essence, the tag column represents the codification of the original text
+data into a structured dataset. This dataset, in turn, can be used for further research and analysis.
+52
+
+id
+vendor
+effective-date
+nopoach
+app-7653
+Acme Inc. 1
+3/24/17
+1
+app-15957
+Acme Inc. 2
+9/20/19
+1
+app-1853
+Acme Inc. 3
+4/3/15
+1
+app-7888
+Acme Inc. 4
+3/28/17
+1
+app-18366
+Acme Inc. 5
+6/25/20
+1
+app-23189
+Acme Inc. 6
+3/11/22
+0
+app-22302
+Acme Inc. 7
+11/1/21
+0
+468744
+Acme Inc. 8
+1/17/13
+0
+app-14481
+Acme Inc. 9
+4/11/19
+1
+app-14643
+Acme Inc. 10
+7/22/19
+0
+Figure 17: Random Sample from the nopoach Database
+53
+
diff --git a/i9FAT4oBgHgl3EQfaB2u/content/tmp_files/load_file.txt b/i9FAT4oBgHgl3EQfaB2u/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..41518920f01e705cc9e7c9934e08f926bcfb6c0f
--- /dev/null
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@@ -0,0 +1,2861 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf,len=2860
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='08549v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='CL]  20 Jan 2023  Transforming Unstructured Text into Data with Context Rule Assisted  Machine Learning (CRAML)  Stephen Meisenbacher∗†  Peter Norlander∗‡  January 23, 2023  Abstract  Abstract: We describe a method and new no-code software tools enabling domain ex-  perts to build custom structured, labeled datasets from the unstructured text of documents  and build niche machine learning text classification models traceable to expert-written rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The Context Rule Assisted Machine Learning (CRAML) method allows accurate and repro-  ducible labeling of massive volumes of unstructured text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML enables domain experts  to access uncommon constructs buried within a document corpus, and avoids limitations of  current computational approaches that often lack context, transparency, and interpetability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In this research methods paper, we present three use cases for CRAML: we analyze recent  management literature that draws from text data, describe and release new machine learn-  ing models from an analysis of proprietary job advertisement text, and present findings of  social and economic interest from a public corpus of franchise documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML produces  document-level coded tabular datasets that can be used for quantitative academic research,  and allows qualitative researchers to scale niche classification schemes over massive text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  CRAML is a low-resource, flexible, and scalable methodology for building training data for  supervised ML.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We make available as open-source resources: the software, job advertisement  text classifiers, a novel corpus of franchise documents, and a fully replicable start-to-finish  trained example in the context of no poach clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Keywords: labor markets, data creation, text classification, hybrid system, big data  ∗Equally contributing authors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We are grateful for support from the Economic Security Project Anti-Monopoly  Fund;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Loyola Rule of Law Institute;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Loyola Quinlan School of Business;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and Loyola University Chicago.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We also  thank Patricia Tabarani, Eric George, Steve Sauerwald, and Chris Erickson.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  †Technical University of Munich, School of Computation, Information and Technology  ‡Loyola University Chicago, Quinlan School of Business  1  1  Introduction  Advances in computational methods offer new ways to gain insight from large volumes of unstruc-  tured text, and yet these methods each have significant limitations, tradeoffs, and a lack clear  guidelines [99].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Despite the advances in Natural Language Processing (NLP), Machine Learning  (ML), Artificial Intelligence (AI) and more recently Deep Learning (DL), there is still “the herculean  task of finding constructs using full-text search” [79, p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 547].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Unstructured text lack a schema, are not standardized, have multiple formats, and come from di-  verse sources [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Greater attention and systematic research is needed to develop processes to create  structured data from unstructured text [45].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A lack of structured information is a barrier to un-  derstanding for researchers and organizations: “as much as 80% of an organization’s data is ‘dark”’  [78].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For knowledge professionals, just-in-time access to domain specific document repositories is  vital, but knowledge must first be codified [114].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Zettabytes (ZB) of new data are produced daily  [20], and roughly 80% is unstructured [67].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While the manual expert labor required for qualitatively  coding novel classification schemes is hard to scale, statistical packages, many information systems,  and quantitative social scientists expect data to be codified and in a regular format: “tabular data  – variables in columns, cases in rows” [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  ML and AI are potential solutions, but require structured training data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Hand-coding by experts  is required in many domains, but does not easily scale.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To address the disjunction between these, we  describe a method that bridges expert-built set of context rules scaled to classify unstructured text  and build training data for machine learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Context Rule Assisted Machine Learning (CRAML) is  a hybrid method for structuring textual data from large-scale corpora into datasets ready for training  ML models and quantitative research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  CRAML begins with a workflow common in qualitative  manual coding research, and ends with ML models trained on text input data shaped by a qualitative  coding scheme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML is useful for qualitative and quantitative social scientists: it empowers  domain experts to efficiently mine volumes of text and scale classification schemata, and it yields  tabular data that captures the occurrence of concepts within a corpus of documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  This paper contributes to information systems research on the design of intelligent systems that  can generate economic and social value from unstructured data [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' By clearly defining the problem,  managing the training data before AI is attempted, and affording users the opportunity to evaluate  and adjust both inputs and outputs, CRAML addresses major concerns identified in research on  AI [131].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This is the first paper to offer a thorough description of a versatile method with the  potential to empower advanced users of an ordinary desktop computer to build machine learning  classifiers and rectangular datasets from unstructured text according to the users’ desired scheme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Expert built rule-assisted machine learning models have been described in the literature, and found  to outperform benchmark methods and professional perception in critical cases such as detecting  persons in states of emotional distress [35].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In addition to describing the method, we call and set  new standards for transparency and interpretability of research on text-to-data machine learning,  and demonstrate the high utility of this approach in three applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In this methods paper, we highlight the need for the CRAML tool and demonstrate its versatility  through applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' First, we use CRAML to perform a simple literature review that highlights  current approaches to analysis of large text corpora in five top management journals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Second, we  release machine learning classifiers with the potential to enhance labor market efficiency, and set  a new standard for transparency for research studying job advertisement text, where underlying  data includes proprietary data obtained under license.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We release ML classifiers, and the rules that  created them, to enable other researchers using job advertisement text to replicate and interpret our  approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Last, we publish a new and massive document corpus of mandatory franchise disclosure  2  documents and present a start-to-finish analysis to enable a full replication of our process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We  detect thousands more plausibly illegal “no poach clauses” that could violate state and federal  antitrust law than found in earlier research [77].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We release a rectangular dataset that represents  the prevalence of suspected no poach clauses that restrict the ability of franchise firms to recruit  employees from other companies that belong to a franchise system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As part of the contribution of  this work, we publish everything needed to fully replicate the no poach analysis: the original PDFs  and the machine readable text of the franchise documents, CRAML software, the manually coded  inputs that creates the structured, labeled data output, the training data, and a ML classifier to  detect suspect no poach clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Section 2 reviews the well-known challenges CRAML was created to address and illustrates the  frequency of current approaches in the management literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Section 3 introduces and provides  detailed motivation for our solution in the context of job advertisement text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Methodological detail  on CRAML and empirical analysis of franchise no poach agreements is in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A more technical  methodology is described in Appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Section 5 provides future directions and discussions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2  The State of the Art  Across many fields of research, methods for analyzing unstructured text are needed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Below, we  highlight literature in management, information systems, computational social science and com-  puter science on: machine learning (ML), artificial intelligence (AI), natural language processing  (NLP), topic modeling and Latent Dirichilet Allocation (LDA), linguistic inquiry and word counting  (LIWC), computationally aided text analysis (CATA), and text or document corpora.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We used the  CRAML software to narrow our search for relevant literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We obtained a corpus of 1,994 pa-  pers published from 2015-2021 in 5 top empirical management journals (Academy of Management  Journal, Administrative Science Quarterly, Journal of International Business Studies, Organiza-  tion Science, and Strategic Management Journal).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Within the management literature corpus, we  searched for papers that could illustrate the use of a method for turning unstructured text into  data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In Appendix A, we provide additional detail on how CRAML can be used in bibliographic  research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Word Counting Approaches (LIWC, CATA)  Computer-aided text analysis (CATA) and Linguistic Inquiry and Word Count (LIWC) are two  popular techniques used in the management literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Experts develop lists of words or dictionar-  ies that correspond to an overall construct and measure the occurrence of keywords inside specific  documents [110, 109].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Researchers often use LIWC standard dictionaries to detect common con-  structs, such as positive / negative sentiment in a corpus of tweets [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Using these methods,  researchers can also develop custom dictionaries to capture previously unstudied phenomena within  an environment: for example, to measure how actors use specific cultural toolkits in a field of action  [125].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such efforts are typically first driven by deduction (keyword selection) and then interrogation  of text (examining n-grams and short excerpts of text containing keywords) [90].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  We developed keywords deductively (available in Appendix A) and narrowed our search for  relevant papers using CRAML.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML output indicates whether each academic paper in the  corpus contains keywords that fall within a given construct (or tag): we focused on a subset of 110  papers that contain reference to text data or a document corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Figure 1 shows that text corpus  analysis and CATA along with it have grown over time;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 88 of the 110 papers that mention a text  corpus also refer to CATA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  3  Figure 1: Counting Words: The Growth of Management Papers Using Text Data and CATA, AI,  ML, LDA, NLP  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Limitations of Keyword-Based Approaches  Conceptual schemes that rely only on keywords are not very rich [46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Constructs may not be well-  captured by word frequency approaches used in CATA and LIWC programs;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' these methods perform  less well than ML at tasks such as inferring personality [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Word counting assumes that all word  occurrences equally contribute to the measurement of a construct - that every use of the keyword  “artificial intelligence” or “machine learning” captures both papers that use an AI or ML method,  as well as those that study or mention AI and ML phenomena.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Because the method relies on exact  matching and correct spellings, CATA and LIWC will fail to recognize concepts when faced with  messy data or typos.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Without the benefit of context surrounding the keywords, key meaning and  accuracy are lost to the user.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' When describing the frequency of terms inside a document, CATA  methods do not typically adjust for document length, although additional steps can be taken to  make adjustments [66].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  While keywords can start a search for relevant concepts, rules and qualitative coding pinpoint  only the relevant text within the documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Qualitative researchers who seek to inductively build  theory typically begin by engaging in keyword search, but also engage in qualitative hand coding  [84].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Unsupervised Learning (Topic Modeling and LDA)  Text clustering aims to solve the problem of information overload by simplifying a mass of text into a  smaller number of meaningful categories.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While many text clustering methods exist [10], a popular  technique is topic modeling, which aims to learn “topics” from an unstructured collection of text  documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Data is often first heavily pre-processed (stemmed), stripped of common words, and  converted into a document-term matrix, which leaves only the stems of latent keywords appearing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Latent Dirichlet Allocation (LDA) assigns all words in a document to a topic, under the assumption  that every part of every document contributes to some topic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' LDA’s versatility is that it is not  domain-specific: it can be used to study hacker forums [129], why people retweet [56], online  communities [18], and discourse on emerging technologies like blockchain [92].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' LDA can also assist  in inductive theorizing [111].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4  35  30  25  20  15  10  5  0  2015  2016  2017  2018  2019  2020  2021  Text or Document Corpus  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CATA  Proprietary Data or Models  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Topic Models or LDA  ML  ··NLP  AlOf the 110 text corpus papers in the management literature, 11 papers discuss the use of this  method, with 5 of these papers appearing in 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' [36] use LDA to arrive at text-based measures  of corporate dissimilarity from corporate annual reports, and use 25 crowd-sourced MTurkers to  ensure themes are reliably identified for the top 25 of 125 latent topics chosen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' [58] use LDA on  annual reports and conduct a semantic network analysis to illustrate the connections and develop  grounded theories of how firms interact with the legal environment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' [73] use patent text to study  the recombination in breakthrough innovation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' [112] study abstracts within a citation network.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [37] use topic models to analyze CEO text and synthesize analysis of topic models using machine  learning analysis of CEO facial expressions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Limitation: Meaningless Output  Latent themes that emerge inductively are meaningless and un-interpretable absent additional data  (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=', facial expression analysis to match themes (ibid)), or expert or crowd-sourced judgement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  LDA assumes that all of the text in every document inside a text corpus is assigned to a theme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  This is unwarranted if an expert has only a niche interest in a particular phenomenon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Papers we  reviewed address this concern by limiting the scope of their corpus, or by extensively pre-processing  to remove potential noise, but this also removes potentially relevant context and data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A second  assumption of topic modeling approaches is that one must know the number of topics that exist  within a collection of documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This is non-trivial, particularly with massive corpora.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Finally, topic modeling imposes an assumption that a researcher be interested in an “unbiased”  representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Experts often disagree about the interpretation of text, and a quest for unbiased  (as opposed to transparent and replicable) analysis may be misguided [97].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Ultimately, unsuper-  vised computational methods face difficulty producing meaningful results in the absence of human  involvement and expert interpretation [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  The Modern ML Paradigm  Supervised machine learning (ML) models are widely used in many commercial applications: to  evaluate candidates for employment [38], to support managers in giving employee feedback [120], to  moderate text content on the internet, judge the sentiment of customer-written reviews [86], and to  build proprietary datasets for financial and academic use.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Widely available ML methods can train  a model to learn academic constructs and scale such models over vast volumes of unstructured text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  However, computational models of text often struggle to provide insights that are interpretable,  and may be perceived as too difficult for low-resource users to access.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Among 10 papers in the  management corpus discuss ML, and four more that discuss AI, we could not locate any that  describe the development of a new academic text classification model that is used to construct new  data from unstructured text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  While general AI and ML tools rapidly advance, there is a great need for applications in spe-  cific domains, such as detecting banking fraud [4] or fake websites [3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Human-in-the-Loop” or  hybrid systems are increasingly prominent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1 The idea of human-in-the-loop for AI applications is  promoted by [130] as a way to introduce responsibility into intelligent agents, as well as to increase  interpretability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Likewise, human-in-the-loop for ML and NLP is particularly promising, both for  data preprocessing and model learning [127].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Efforts to use AI and exclude domain experts are  1Hybrid systems are not novel, with discussions already spanning decades.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For example, placing a human in the  loop was proposed in the design of “socially intelligent agents” [43].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' More recently, human involvement in security  settings [40] and cyber-physical systems [107] have appeared in the computer science literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  5  likely to fail, as shown in a study of how AI use in hiring decisions evolved into hybrid practices  [28].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Many AI systems cannot (and arguably should not) be trained without human oversight, and  thus such intervention is vital to incorporating the necessary human knowledge into these systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Even with a human-in-the-loop approach, challenges have been noted, for example by [128],  which among others includes the ability to analyze the impact changes with iterative human in-  tervention.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For academics in management and information systems, incorporating the knowledge  of domain experts into the process of building structured data is essential for both deductive and  inductive study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such domain knowledge is crucial to forming the essence of training data, which  necessarily represents some aspect of the worldview of a human who chose to train a model from it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For supervised ML, challenges lie not so much with the ML methods or models themselves, but  with the paradigm for ML.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The process by which ML models are built (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' how information is  learned) is opaque at the outset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Supervised methods in the Modern ML paradigm, and existing  tools for the ML pipeline, do not give experts the ability to easily create training data and thus  train a simple model that can scale over vast quantities of text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As discussed by [7], much of the  attention around Explainable AI (XAI) has been placed on “the way in which models behave,”  seeking meaning and interpretability in the outputs of models that can often be highly opaque.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If,  instead, experts could easily build and curate training datasets, there would be greater opportunity  to build interpretable models accepted by experts and members of the relevant audience.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Labeled training data is the critical input to supervised ML models to code future, unseen text  instances.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' What we call “the Modern ML Paradigm” for supervised learning of text data largely sees  training data only as input, and holds the interpretability and explainability of ML model outputs  as a post hoc concern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If building custom training datasets for text were easier, then resulting  models can be interpreted – and modified – at the input stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Expert-curated ML models could be  interpretable and put into action in a domain, and escape some of the limitations of the modern ML  paradigm: black boxes, proprietary training data, and un-reproducible, meaningless output that  exclude participation from voices without supercomputers or advanced computer science knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Limitation: The Black Box of Supervised Learning  The “Black Box” refers to the mystery by which textual inputs are categorized by machines leading  to certain outputs and are rooted in increasingly large model architectures and consequently, how  computational models memorize, rather than truly learn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In turn, one is often hard pressed to  decipher the behavior of a classifier, even with state of the art models – they simply reflect patterns  observed during training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Trust requires understanding “what the machines are doing” [33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the modern ML paradigm,  attempts to “explain the black box” often come after the fact, which [12] calls “Post-hoc Explain-  ability”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Here, when faced with models that are not interpretable by design, one may try to boost  explainability after the fact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As [12] writes, post-hoc approaches have become the de facto way of  achieving some level of explainability with complex DL models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Without understanding the data that goes into training the model, the explainability of the  modern ML paradigm is limited.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In a recent survey of explainability in supervised ML methods,  [30] call for rethinking the problem from first principles, and encourage researchers to ask “What are  we actually looking for?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Do we really need a black box model?”' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For many experts, the immediate  answer is no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Even a ML model with a high degree of predictive power is likely to be seen as  undesirable if it does not produce interpretable results [97, 95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Underspecification can result from training models on massive volumes of data and selecting  the model(s) that achieve a desired predictive power [42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Underspecification often leads to failure  6  when those models are used outside of the context in which they were trained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As [69] writes: “the  process used to build most machine-learning models today cannot tell which models will work in the  real world and which ones won’t.” [65] calls for greater interaction between humans and machines  and for explainability when models are faced with new situations – a “sign of mastery.”  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Limitation: Proprietary Training Data and Methods  Seen from a different angle, black boxes may be valuable in order to protect trade secrets hidden  behind such trained models [105].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Secrecy presents risks in the cases where “high-stakes” decisions  are made by the models in question, having potentially significant societal or economic implications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Academic users often rely on commercial data providers that give little to no insight into their  proprietary process for data creation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In our analysis of the management literature, 13 of the  100 text analysis papers, and 117 papers in total indicate the use of licensed, proprietary data  or models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The problem identified by [81] is that such computational methods could become the  “exclusive domain” of private companies and government agencies that operate contrary to the  academic commitment to openness.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The inadequacy of data-sharing paradigms for big data cast  doubt regarding the veracity of ML models [82].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Private firms and academics typically advance the state of the art by breaking new records  for the complexity of data, the size of models, and the number of parameters in a model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Many  potential contributions from researchers who lack access to super-computing resources, the funds  to buy large proprietary datasets, or access to confidential government data are excluded [32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Our  search for management papers that indicate proprietary data or models illustrate stable trends over  time, but when big or secret data outputs become the criteria through which the quality of research  is judged, only those with access can compete, and there may be less attention to “cumulative  progress toward answering important questions” [44].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  By reducing the need for humans to think, act, or belong (contribute, be included) in the public  sphere, [72] write that ML systems can constrain and oppress, rather than achieve emancipatory  goals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To deliver on the potential of ML, improvements needed include greater sharing of data, pro-  tections for privacy to enable more open data, intellectual property standards to reduce transaction  costs, and approaches that enable genuine replication [75].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Pre-processing of datasets for supervised  learning could be a core strength and contribution of social scientists in analyzing text data [45].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Despite advances, DiMaggio’s (2015) call for greater systematic research to develop solutions for  curation challenges and guidelines for pre-analysis and developing training data has largely been  unmet.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  Limitation: Meaningful Contributions to Knowledge  In a statement that rings true almost a decade after it was written, there is little evidence of com-  putational social science in leading social science field journals [124], or in the management corpus  reviewed here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Computational social science methods have advanced significantly, but it has yet  to be demonstrated how computational scientific infrastructure can be applied to important social  problems [82].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Disciplinary silos, privacy concerns, and unreliable, non-replicable, and proprietary  2One promising approach is computational grounded theory: a novel framework to use unsupervised machine  learning to identify patterns, engage a human in interpretive refinement of patterns, and use computational methods  to assess and confirm identified patterns [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This “human-centered computational exploratory analysis” is pro-  posed to help social scientists benefit from unsupervised computational methods and enhance the transparency and  reproducability of content analysis [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  7  data hamper the potential for computer science methods to provide meaningful insight into society’s  challenges [82].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The emergence of a computational social science apart from traditional academic disciplines  speaks to the hope that ML and AI can advance knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' However, the possibilities of these  technologies are lessened when such tools are perceived as beyond the reach of ordinary users [48].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Less than a decade old, some such initiatives, such as “data science for good”, have been criticized for  not giving the social sector “the opportunity to design for what we want” [101].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Without tools that  enable domain experts to develop their own ML models, there is a risk that new interdisciplinary  or trans-disciplinary centers might lead to yet another siloed academic discipline as ill equipped to  solve problems as others [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Future opportunities for AI identified by [21] include democratization,  reducing requirements for data, and enhancing AI explainability and transparency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  [122] attributes a “Hyper-Focus” in current ML research to three causes that have led it to  lose “its connection to problems of import to the larger world of science and society.” First, the  (over)use of benchmark datasets, many of which are “synthetic”, has “glaring limitations” and still  make reproducability difficult.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Only 1% of ML papers are applied to a specific domain and the  rest use benchmark datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4 By way of contrast, [79] report that 90% of research constructs are  uncommon, suggesting that using pre-labeled standard benchmark data for training will miss entire  vast areas of domain-specific knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Secondly, the focus on “abstract metrics” like F-scores  to determine model quality across domains is a “mirage” that masks the need to focus on impact  and usefulness of a model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A final issue is the “lack of follow-through,” suggesting that current  computational research leaves little incentive for connection to sustained research agendas.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  A related concern is the rapidly depreciating relevance of data that many ML models are trained  on [82].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the ML training process, models are trained “in the lab” on a training dataset, yet  the environment in which models are deployed is dynamic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Big data” research may apply only  to specific users of a specific portal at a specific time in which a study is conducted [68, 100].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For that reason, online studies and experiments with large response rates may fail to produce  reliable or general knowledge [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A static training process may simply not reflect the real world  environment or its rapid evolution [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The velocity of internet-based data also creates a limitation  for computational social scientists’ conclusions [93].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Solutions to these obstacles include forming  new multi-disciplinary, international journals that permit rapid publication of rigorous quantitative  descriptions of rapidly evolving phenomena [94].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4  Seeking Explainable Tools for Social Science  To sum up the issues described in this section, each method reviewed has strengths, limitations,  and tradeoffs for experts who seek to analyze unstructured text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For domain experts with an  interest in specific phenomena, the methods reviewed so far do not allow for expert-led, targeted  extraction of niche constructs hiding within corpora and the construction of standardized data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For  many qualitative researchers, the systematic analysis and discovery of new patterns within domain-  specific digitized records is a core contribution – the ability to find the diamond (a single topic)  in the rough (lots of text).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If qualitative hand-coded contributions could be easily scaled, it can  address some issues found in the supervised ML domain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  3Emerging paradigms for low-resource Natural Language Processing (NLP) seek to eliminate barriers to accessing  ML technology [71].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4Classic examples of these datasets include the Movie Review Dataset [87] or the Yelp Review Dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While use  of standardized datasets may reduce the reproducibility crisis in ML [74], there is a tradeoff.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As one might imagine,  benchmark and standardized datasets have limited application to the real world;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' furthermore, many benchmark  datasets are tailored for specific tasks, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' movie reviews are often used for sentiment analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  8  3  Context Rule Assisted Machine Learning (CRAML)  Enabling experts to create training data for niche classifiers to detect constructs that are relevant  within a specific domain would address many of the problems identified with the modern ML  paradigm, and the limitations of unsupervised computations methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The CRAML method we  present emphasizes explainability and has a contribution on each of the six dimensions that explain  the performance of AI systems according to [13]: the models are specific to a single construct,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' the  goals are clear,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' by limiting the chunk size and extracting text from documents in the corpus,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' the  training and input data is intended to be context-specific,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' the output data is interpretable (a 0/1  binary classification),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and the environment is also intended to be domain specific and expert-guided.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  By emphasizing the “human in the loop,” CRAML gives qualitative and quantitative researchers  control over the training data that is the key input to ML models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This offers new capabilities to  control the analysis and measurement of phenomena found in massive volumes of unstructured text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  This section briefly introduces the solution developed and explains how the solution addresses the  problems described above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  A Framework for Unstructured Text Analysis  CRAML software gives users the tools to manipulate keywords to extract relevant data from massive  corpora, create “tags” that seek to capture topics or themes, and subsequently, develop “context  rule” sets that codify knowledge about the specific pieces of text that correspond to specific tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The CRAML process yields tabular output that matches document-level metadata with a 0/1  indicator that symbolizes the occurrence of tags in a document [80].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Figure 2 provides a high-level overview of the CRAML framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The CRAML process begins  with the full text of a corpus of documents (Step 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While metadata is not required, CRAML soft-  ware is designed to combine characteristics extracted from the text with metadata at the document  or record ID level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In step 1, the researcher chooses keywords to extract from the corpus, and retrieves a “chunk”:  a block of text containing a user-selected number of words surrounding the keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The chunk  length should contain the full “context window”: all of the relevant context for a human to determine  if the keyword-containing chunk is relevant or not for some binary classification schema.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The user  can extract all chunks from all of the documents in the corpus, or in low-resource environments,  can randomly sample from the documents in order to perform Steps 2-4 on a smaller subset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In step 2, the researcher analyzes the patterns within the chunks, studying n-grams that reveal  the most common phrasings surrounding the keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In step 3, the researcher writes “context rules” that elaborate an ever-more detailed scheme of  binary classifications of the chunks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We refer to these binary classification schemata as “tags”: each  tag represents a topic or theme that the researcher defines by recognizing patterns in the extracted  text and determining if each chunk is (tag=1), or is not (tag=0), illustrative of the tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' There is no  limit on the number of tags a researcher can define.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For each tag, there is no limit to the number  of rules that can be defined using either exact text matching or regular expressions (RegEx).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In step 4, the researcher written context rules are applied or “extrapolated” over either the full  extracted chunks or a sample of the extracted chunks to create a training dataset for ML modeling.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Extrapolation labels each chunk with a 0 or 1 for each “tag,” or binary classification scheme, and  creates a dataset that can be used for training ML models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In step 5, common ML algorithms  use the training dataset to tag the full extracted chunks, and the researcher identifies the best  performing model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the final step, the results are aggregated into a document-level database  9  Figure 2: A Simple View of the CRAML Process  of structured information: for any document within the text corpus, the researcher knows if the  document contains a tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Additional hand-coding by independent third-parties can validate that  the training dataset extrapolation, and the ML results, are highly accurate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Versatile tools for mixed approaches  CRAML’s pipeline incorporates a novel set of tools that  provide an end-to-end solution to the challenge of structuring unstructured text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' However,  researchers may appreciate its flexibility and multiple uses: a researcher may wish to pursue analysis  using only pieces of the CRAML process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The proposed system is not a rigid algorithm, but rather  a flexible pipeline of tools created to implement a research framework that was developed to address  a specific research task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As [99] note, choosing between a dictionary, rules, or supervised machine  learning involves tradeoffs, and no clear guidelines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In CRAML, particular steps and technologies  can be interchanged according to the user’s preference, skill set, and research challenge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A qual-  itative researcher can quickly sample and sift through text data and experiment with alternative  classification schemes and definitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='5 For another researcher, extraction could be a pre-processing  step before engaging in a computational grounded theory project that uses unstructured NLP meth-  ods once the plausibly relevant themes are extracted based upon keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A third researcher may  wish to extrapolate a full dataset without ML.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A fourth researcher may wish to only sample a mas-  sive corpus, extract context windows around keywords, and inductively generate topics or themes  with extracted text and have no desire to perform further computational avenues of analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  5Emerging paradigms for low-resource Natural Language Processing (NLP) seek to eliminate barriers to accessing  ML technology [71].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Particularly with low-resource NLP, the availability of labeled data, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' text, become crucial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  10  The CRAML Pipeline, Simplified  Text Corpora  Any collection of unstructured text data  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e:documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  0  (job postings;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' legalicontracts;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=")  Keywords: 'solicit." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content="hire'." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=" employ'." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Extractchunkswithkeywords  Chunks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' context window around keyword  N-grams: common n-sized text chunks, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content="  Learn rules with n-gram patterns  'shall not solicil is a common 3-gram  2  Tag a sample via rules to create  Using expert-created rules, label documents witha  3  training data  matching: identify qualifierwords (e." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g: negation)  Using the training data created in step 3,  Learn ML models  train Ml models, ie binary text classifiers  4  Create  Classify the entirety of the text corpus, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' label all documents with the  given tag(s): The result is a structured, relational database where each  5  Database  entry corresponds to a document from the original corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  A Bridge to Solving Real-World Problems  By positioning context rules as the crucial bridge between domain expert knowledge and structured  datasets that represent embodied knowledge, CRAML provides a “traceability” from datasets clas-  sified by ML models back to the context rules that lead to them – and the humans who wrote  those.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' By placing a focus on explainability at the first bridge from unstructured data to structured  data(sets), the second bridge from training data to trained models becomes easier to cross.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' ML  modeling “presumes a world of already existing (divine or rationalistic) rules, which only need to  be formalised, in order to make sense to a machine (or an analytical philosopher for this reason)”  [11].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Context rules in CRAML codify which text belongs to which topic or theme according to the  user.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To the extent such rules can be articulated consistently, then they can be extrapolated over  unstructured text to create fully structured datasets to train ML models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Rather than presuming unbiased training data, CRAML extends the user’s worldview to the  realm of ML models via expert-created context rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Interpretive frameworks lend meaning to  text and are a cornerstone of academic research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Scaling methods such as coding and grounded  theory over large volumes of text contributes to theory development [117].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Rigorous manual content  analysis by qualitatitve social scientists is often geared toward the induction of topics and themes,  yielding new constructs, analytical frameworks, or mid-level theory of some phenomenon [59].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6  Alternatively, a quantitative or hypothesis-driven researcher might pursue evidence of a phenomena  within a text corpus, quantify its frequency, and then analyze it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In CRAML, the use of context rule sets serves as the foundation for representing the knowledge  of a domain expert, without the need for explicitly annotating all unseen instances (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' documents).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Through the extrapolation process, the hybrid CRAML framework requires manual work only in  the crucial first stages, and leaves the remainder to automation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML’s initial step is similar  to processes used in IS research: for example, to develop a specialized ontology of hypotheses,  [85] couple rule-based approaches for extraction and word embeddings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The “human in the loop”  contributes transparent manual codifications of text, which allow for the replicable and configurable  construction of tabular datasets used either immediately for quantitative social science analysis, or  to train ML models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='7 Because CRAML involves human expertise and gives control over training  data to the user, the ML model that results from CRAML is interpretable as a product of a human-  built and curated rule set that can be published, and then contested, examined, and modified by  others.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This mitigates concerns over black box ML models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  CRAML built models can have real-world applicability, because training data and ML-built  datasets can be formed by domain experts who largely address Wagstaff’s (2012) concerns regarding  abstract metrics and lack of follow through.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Empowering users to create novel, meaningful datasets  and ML models in their worldview also enables rapid changes that can be put into action locally.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  This comes at a time where novel ML or DL approaches can be severely limited by available datasets,  with no widely accepted approach to create novel ones as needed and in an efficient manner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  As a final response to the challenges introduced in the previous section, CRAML’s methodologi-  cal transparency is intended to address several of the problems with proprietary data and otherwise  6For scientific purposes, inductively derived analytical frameworks from text should be a) intra-subjectively  reliable, b) inter-subjectively reliable, and c) fully reproducible [95].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This means that a single person should reach  the same coding conclusion again and again, a second person should reach the same conclusion, and the methods,  data, and analysis should be transparent enough to permit replication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  7Explainable and interpretable models can be built when users “steer learning” through feedback and interaction  [65].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' [7] writes that “explainability can only happen through interaction between human and machine.” Of course,  the creation of such hybrid system requires expert human labor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' [105] writes that “[i]nterpretable models can entail  significant effort to construct, in terms of both computation and domain expertise.”  11  unreachable methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  With a standard desktop computer and open source software, CRAML  enables interactive engagement with massive text corpora without prior programming knowledge  (although users will find some programming knowledge helpful and advanced users may seek to  customize the underlying code for niche purposes).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' At each crucial step of the framework, CRAML  saves and shows the user the underlying data in CSV format in order to enable the interactivity es-  sential to truly achieving a “human in the loop” and records each step of the process for replication  and transparency purposes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  By making the framework as open and transparent as possible, and publishing the code base  and the underlying data used here, we provide opportunities for users to test, harness, or modify  the framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML software is available under a under a Creative Commons Attribution-  NonCommercial-ShareAlike 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0 International License.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The artifacts created and used by CRAML  in the intermediate stages are extracts and samples of the plausibly relevant text from a document  and document corpus using keywords and context windows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A user can control what information  is extracted from the corpus, and thus remove sensitive data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Thus, CRAML can mitigate some  privacy protection and sensitive information concerns that limit access to sensitive data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Other  researchers working with big data have taken a similar approach by extracting only relevant pieces  of larger documents [113].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' By  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  An Application of CRAML: Job Advertisement Text  Job seekers face difficulties finding the right jobs, and employers face frictions in job search that  represent additional recruitment costs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Search frictions harm both workers and employers by in-  creasing the barriers to good matches in the labor market, and reducing competition for labor  [29, 89].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A suite of ML classifiers that added niche filters to job search engines could benefit job-  seekers, employers, and workforce agencies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' With support from the National Science Foundation,  the National Labor Exchange created the NLx Research Hub in 2021 to “increase the amount of  actionable labor market information in the U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' to facilitate the recruitment,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' hiring,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and training  opportunities of American workers” and “deepen partnerships between industry,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' government,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and  academia by enhancing the infrastructure to support the convergence of research,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' education,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and  talent pipelines.”' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Workers who desire more flexible,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' remote jobs after COVID-19,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' disabled workers seeking specific  working conditions,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' union workers,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' workers with a professional license,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and veterans as well as  veteran’s spouses may all be underserved even while being preferred by specific employers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  An  employer can gain a competitive advantage by hiring workers who are otherwise discriminated  against, but only in an efficient and competitive labor market [19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Job seekers may easily become  discouraged without information on whether, for example: a job is located near public transit,  or whether an employer will interview an ex-felon, a teen, or a non-resident on a visa.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If some  employers seek to target and hire underserved audiences, but job ads never reach the workers, then  research should aim to reliably identify which jobs might be especially relevant for a particular  worker.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Research application  CRAML was first developed using job advertisement text data to support  research on the labor market.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While the underlying text is confidential and licensed, we describe and  release rules files and nine ML classifiers that achieved a high accuracy in detecting job characteris-  tics and barriers to employment under a Creative Commons Attribution-NonCommercial-ShareAlike  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0 International License.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The research implications of this work are not only immediate research  papers, but a potential to release custom-built ML classifiers and create open tools for real-time  12  information systems that track changes in the labor market.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such application could improve both  research and contribute to reducing barriers to employment in job advertisements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Ultimately, bet-  ter data on employment practices obtained from job advertisement text and other sources of text  information could have a profound impact on research capabilities in this field.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='8  In Appendix B, we provide a list of tags and the keywords extracted as part of an effort to  identify specific barriers to employment, the accuracy of the models built, and discuss how the  broader labor market research community can contribute to this effort.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4  A Step-by-Step, Replicable No Poach Classifier  We demonstrate the start-to-finish CRAML approach by applying it to an empirical context where  the resulting analysis might be meaningful, transparent, and replicable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Toward this end, we con-  tribute a new text corpus of 151,708 franchise documents, and the cleaned and pre-processed text  we used in this analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We publish metadata that tracks which of 12,992 records a particular  document corresponds to, and includes the effective date, company name, and unique ID.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We also  publish the rule sets that are the manual hand-coded input, enabling replication and scrutiny of  the results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We also publish the training dataset and the ML model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Empirical and Data Context  “No poach” clauses in contracts are also referred to as collusive pacts or anti-competitive restraints  on employee mobility, and have drawn interest from academics, regulators, and policy-makers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  While anti-competitive language is contained in public documents, sometimes contrary to public  policy, these documents are inaccessible for many: available only in massive, unsearchable collections  of PDF documents on state agency websites.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' With subtle variations in language and no guide about  where to look for these clauses, no poach clauses are diamonds in the rough: a few sentences in  hundreds of thousands of documents with millions of pages.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Indeed, such clauses were largely not  known to exist by the relevant academic and policy community of interest until the release of a 2017  working paper published as [77].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The paper contained a limited sample and relied on a third party  data provider to identify no poach clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Following the release of the working paper, eleven state  attorneys general issued a letter in 2018 demanding the practice end, many franchises voluntarily  ended the practice, and the State of Washington in 2018 first negotiated settlements with franchise  companies in which many removed their no poach clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Both no poach and non-compete clauses are known to place downward pressure on wages [31,  17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Given their importance in reducing opportunities for job mobility, there is great interest in  descriptive statistics regarding the prevalence of these clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Overcoming the inaccessibility of  the text within public documents was a significant challenge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We assembled a large collection of  Franchise Disclosure Documents (FDDs) from the state of California by scraping PDF documents  8In ongoing work supported by the Russell Sage Foundation Future of Work Program and NLX, a job-  advertisement level SQL database built from CRAML’s classifiers using NLX data is now operational and new  classifiers are under construction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  9The PDFs are hosted in partnership with DocumentCloud, and will be released upon publication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' On Doc-  umentCloud, where they can now be searched, discussed, and annotated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Additional items will be uploaded to a  scholarly repository upon publication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  10See Washington State Attorney General Report, Letter from State Attorneys General.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As Ashenfelter wrote,  “it is instructive that the mere revelation of collusive agreements, whether legal or not, has so quickly provoked a  strong response from both the antitrust authorities and the franchisors whose agreements contained these no-poach  clauses” (qtd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' in [77])  13  from the public web.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' These records exclude companies that may be exempt from filing, and may  be missing observations due to limitations when accessing data from the web.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='11  In addition, we make available the machine-readable text corpus we build from the downloaded  PDFs and the metadata that ties documents to specific company filings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For pre-processing, we used  Python’s Tika, and for files that could not be initially read with this, we used ABBYY Fine Reader.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For the California corpus, we assembled 151,708 documents in 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='99 GB of cleaned machine-readable  text that can be traced back to a total of 12,992 franchise records.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We consider the record to be  the unique ID that the state assigns to multiple documents from a franchise on a particular date.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  We trace each document back to a record with metadata that includes the name of the franchise,  and the date of the filing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  The Construction of Training Data  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Step 1: Extract Relevant Text to Reduce Information Overload  Figure 3: First process in the CRAML Framework – Extract Data  The extraction process encompasses taking the unstructured text files and preparing a cleaned  dataset of only the text that is plausibly relevant that is ready for hand-coding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' By reducing the size  of the text files being worked with, and delimiting the extracts to the relevant text in the corpus,  this step addresses challenges of computational resource intensity, and assists in sifting for relevant  information in a large corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This is a manual, iterative process – a loop that is exited when  11While we were able to obtain and match the 151,708 documents to the 12,992 records via web scraping, we  identified 16,216 franchise disclosure records from January 2013-July 2022, and are investigating additional methods  to acquire any missing data, which we believe to be randomly distributed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  14  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Extract Data to Reduce Information Overload  ProblemsAddressed:  Siftingforrelevantdata  Chunkextraction with expert guidance on classification  Resource-intensivecomputation  schema (tags),keywords,and contextwindowlength  Irrelevantdataintextcorpus  Enter witha  Expert creates  text corpus  keywordsand  tags  Tags,keywords,  Expertexplores  Expert selects  andcontextwindowsize  No  text_ex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py  contextwindows  finalized?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  n-gramsand  Input:textchunks  adjustskeywords  (N)fortext  Output:n-grams  andtags  chunks  Yes  extract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py  Input:textcorpus,  Runtext  Sampleorfull  keywords,tags,  explorationtool  corpusextract?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  windows size (N)  (text_ex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py)  Exitto  Output:stored  Extract chunks  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Build Rules  chunksincsvfiles  fromcorpus  (extract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py)the user is satisfied that all of the relevant text is extracted from the corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Figure 3 illustrates  the extraction process, which corresponds to Step 1 outlined in Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Two main software tools  (extract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py and text_ex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py) aid the user in finding and exploring the relevant text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  We chose initial keywords “hire”, “recruit”, “employ”, and “solicit” to explore if franchise doc-  uments contain a no poach clause.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The initial keywords chosen suggested additional ideas for tags,  which in turn, suggested new ideas for keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To aid in this process, a repeated N-gram ex-  ploration helped discover the contexts in which given keywords appear the most.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This exploration  prioritizes the extract, suggest new ideas for keywords, tags, rules, context windows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Because the full  context was important to explore initially, the earliest exploratory extracts focused on the 20 words  surrounding each keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Following all of the processes described below, a final context window  of 13 words was selected (6 words to the left and right of the keyword).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The goal when removing  irrelevant or non-essential information is to reduce noise and build a highly focused ML classifi-  cation model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In an iterative and flexible process, more keywords were subsequently added: for  example, “poach”, “non compet”, “noncompet”, “covenant” and “not to compete” simply restarted  the process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Step 2:  From Rule Sets to (Training) Data via Extrapolation, Testing, and  Validation  After the extraction process, an expert conceptualizes and defines the desired classifications, or  tags, and builds a rule set for each tag in a manual and iterative fashion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Figure 4 details the  iterative process of Step 2 in Figure 2 that involves validation, extrapolation, and the refinement of  rule sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This process concludes when the expert is satisfied that the extrapolated rules are valid  on a sample of the text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The rule set is then “extrapolated” to the full extract from the corpus,  yielding a structured dataset of accurately classified chunks – a training dataset, in other words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  As described in the following section, the results of Step 2 can be used immediately for descriptive  research regarding the contents of documents, or as a basis for training ML models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The cycle begins with the initial creation of rule sets for each tag, which can be done manually  by an individual researcher, or team of researchers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Constructing and designing accurate indicators  requires researcher familiarity with ontological subtleties and appropriate construct validation and  scale development methodology [126, 88].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Rules are written in a CSV file that contains a list of  rules, the priority level of each rule, and the corresponding tag, assigned a 0 or 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As earlier, the  N-Gram tool may be helpful – doing this prioritizes the creation of rules that will “cover” the largest  parts of the entire data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Priority level determines the order in which a rule is run.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A earlier rule  can be over-written by a subsequent priority rule.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Step 2 then involves the use of rule sets and the extrapolation algorithm (extrapolate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py) to  validate the rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In essence, the extrapolation process will convert the set of rules into an extended  dataset, and will tag each chunk according to the user’s encoding of each rule.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The resulting  dataset contains the unique document identifier, the extracted chunk matching a certain rule, and  the defined encoding for this chunk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Note that this extrapolation is done individually for each  rule set and tag, thus resulting in a training dataset for each rule set (file).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A second software  tool (validate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py) relates to the validation of the data that is the output of extrapolation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Once  extrapolated, the expert tests the performance of the rules against actual chunks that are coded by  those rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The expert can export a strategic sample of chunks meant to ensure each rule is valid –  choosing a random sample of N examples per rule.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This enables independent hand-coders to score  each chunk, which can then be re-imported to assess accuracy and performance of the rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For the franchise document data, allowing iterative exploration of keywords and adjustments to  15  Figure 4: Second process in the CRAML Framework – Build Rules  rules, we developed a set of over 500 rules and 6 tags to classify suspect anti-competitive clauses  in the corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We first focused on finding all employee “no poach” clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As one rule for the no  poach tag states: “you may not seek to employ or retain any employee or independent contractor  who is at any time employed by us.” When examining similar extracted chunks, we found that many  documents also contained language that went further than prohibiting an employer from soliciting  another party’s employee, but also prohibited an employer from hiring or employing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We create  a separate tag these “no hire” clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such “no hire” clauses, as in the following example from  the no hire rule set, state that: “party shall not hire or solicit to hire any person employed then or  within the preceding year by the other party.”  Independent validation in which a third researcher hand-coded 706 chunks indicates an initial  91% match between an independent third party and the extrapolation of rules, suggesting a high  degree of inter-rater reliability in ability to detect characteristics of no poach clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While our  emphasis here is to ensure that there is strong inter-rater reliability between the CRAML user  and an independent observer in this test example, we do not claim perfect identification of all no  poach clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For a regulator, additional scrutiny would be required, but the overarching goal  is to identify plausibly relevant and/or problematic no poach language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The pipeline enables any  observer to classify the documents according to any arbitrary schema.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We emphasize that CRAML  here enables content validation processes at the input stage to ML.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Independent assessments of  reliability are key to any conclusions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Step 2 Results: A Labeled, Structured Dataset for Analysis  Step 2 yields a dataset for  training a ML classification model, or, if the underlying corpus is small enough (as is the case  here), the rules can be applied to the entire dataset and reveal which filings contain which clauses  16  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='BuildRuleSetsto ClassifyText Chunks  ProblemsAddressed:  Scalingclassificationschemes  Expert-ledrulesetconstruction,extrapolationto a sample  Buildingrepresentativetraining  trainingsetorfull dataset,andvalidationofresults  datafromunstructuredtext  Enterfrom1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Expertwrites aset of  with chunks,  rulesfor eachtag and  tags,keywords,  determinestheirpriority  andn-grams  w.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='ttextchunks  Expertis  (Independent)  No  satisfiedwithrules  validation?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  expertshand-code  extrapolate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py  Text exploration tool  Validationset  Input: rule set(s),  yieldsfrequenttext  extractedtext  patterns  Output:structured  training data  Yes  validation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py  Validate rules  Training data  Input:training data  withselected  orfull dataset  Output:selected  sampleof data  needed?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Exitto  sample,validation  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='ML  metrics  Extrapolate rule seton  Classification  textchunksto create  representative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='dataset  (extrapolate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='py)according to the specified rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  Step 3: Training ML Classifiers to Build Structured Datasets  While the above analysis is based on an extrapolation of rules to all chunks in the dataset, CRAML  yields data that a ML classifier can train.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Although many algorithms exists for such a training  process, the CRAML framework trains a binary classifier for each tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In other words, each training  dataset is created from a rules file, which contains one or more tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Accordingly, each classifier  can be traced back to a rule set to perform a 0/1 classification for the tags included therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The  training process is described in greater detail in Appendix C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Once the classifier(s) are trained, they can be deployed to classify the original data, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' the entire  unstructured text corpus, or can be used on other sources of data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This represents the completion of  the CRAML framework, as one can now build a structured, labeled dataset from the unstructured  text of a document corpus using a ML model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This entire final process is illustrated in Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Figure 5: Third process in the CRAML Framework – Train Classifiers  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  Evaluating the Model  In this empirical context, we train a no poach classifier built with training data from California.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We  use the classifier to build datasets for both California, in order to obtain a comparison between the  rules-based approach and the ML approach using the same data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The “no poach” classifier is built  with training data from a 10% sample plus all of the no poach tag=1 observations in the full sample.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In some cases, when the occurrence of positive or negative tags is very low, manual augmentations  to training data such as this are required in order to receive acceptable model performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We  obtain an accuracy score of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='99, precision of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='97, recall of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='96, and an overall F1-Score of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='97.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  17  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='TrainMachine Learning Classification Models  ProblemsAddressed:  ComplexityofMLtechniques  Learningrobust,generalizableclassifiersbuiltuponthe  Availabilityoftraining data  expert-validatedtrainingdata  Creationofstructureddata  Enterfrom2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  with validated  training data for  ExpertselectsaMe  eachruleset  methodfromanarrayof  availablechoices  Model  Mergeandstore  data (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='to OB)  Learnmodelon  Newrulesornew  training data  model?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Rules  Returnto2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  BuildRules  Expertsatisfied  Finish  No  with.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='metrics?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  YesThe harmonic mean of precision and recall (or F1-score) is based upon a comparison between the  ML output and the training dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A common statistic in ML, with a maximum score of 1 when  precision and recall are perfect, and 0 when either precision or recall is zero, the F1 score suggests  a high level of accuracy and recall between the training dataset and results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Figure 6 displays the percent of all rule-detected and ML-detected no poach clauses in the  California Corpus within each year for each record filed from years 2013-2022 (with partial data  for 2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The pattern depicted with the California data is similar to the rule-based analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' It  shows that from 2015-2017 over 60% of the records contained no poach clauses, after which there  was a decline until the percent stabilizes below 40%.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This suggests that the interventions that  followed [77] had a large effect to decrease the prevalence of anti-competitive no poach language  in franchise documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The continued prevalence of these clauses, despite interventions from  authorities, requires further investigation (in another paper): while the no poach clauses continue  to exist, inspection of the text chunks reveals that while some remain the same as before the  intervention of the Washington State Attorney General, while others now limit their applicability to  more favorable jurisdictions and others restrict their application to highly compensated employees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Figure 6: Analysis of Suspect No Poach Clauses in California Franchise Documents  Practical Note on Model Accuracy  One noteworthy aspect of CRAML is that the above  statistics reflect performance of the model at the “chunk” level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  If an expert were looking to  confirm that certain documents contain no poach clauses, the record is the level of analysis where  they would want to begin their search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Given over 150,000 documents stored in nearly 13,000  18  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='7  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='5  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  0  2012  2014  2016  2018  2020  2022  RuleDectectedNoPoachClauses  --MLModelDetectedNoPoachClausesrecords, this could be a daunting task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Moving to the level of the records, in California, the no  poach classifier closely matches the rule-generated results, with only 22 false negatives and 672 false  positives in 12,922 records.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Thus, at the record level, ML model achieves a 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='95 F1-score, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='996  recall, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='91 precision, and accuracy of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='946.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Further, an inspection of text chunks reveals that a significant portion of the false positives  are in fact related to other language that accompanies no poach clauses and belong properly in  the context of anti-competitive language in these documents: jurisdictional restrictions on no poach  clauses, language that applies no poach clauses only to specific employees, and language that creates  non-compete clauses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Precision at the level of the record would be 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='04 higher (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='95) if one considers  these clauses to be relevant to a search for a broader construct of anti-competitive language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The  results of CRAML are fully traceable to choices made in the construction of a rule set for the no  poach classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As seen in Figure 6, the ML classifier identifies more suspected no poach clauses  then the rules, and this increases in 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Additional research using this corpus is pinpointing  fine-grained characteristics of language in these documents that restrict employee mobility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  A final note: if one were dissatisfied with the model performance and sought one with higher  recall or lower accuracy, or a more or less specific definition of the no poach construct, it would  possible to “steer learning” and achieve a desired result by changing rule sets and thus re-shaping  the training data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If desired, a user could add or remove all jurisdiction, narrow, and non-compete  language from the no poach rule set in order to achieve a more discriminating classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A user  could also combine all of the rules to make a single classifier that memorizes a larger pattern related  to all types of anti-competitive language that appear in the documents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  5  Discussion  The CRAML framework makes several contributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' First, the framework enables the systematic  and structured process of creating novel datasets from unstructured text corpora.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Second, the result  harmonizes advanced, automated information extraction and ML techniques with the input and  expertise from manual analysis performed by supervising researchers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The exploration and iterative  process performed during the context rule creation stage involves work that is not only difficult  to perform automatically, but also that will arguably never come close to matching the diversity  and expertise of human experts with domain knowledge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As a result, this intermediate stage in the  framework incorporates a human element that is lacking in modern classification frameworks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Future Directions  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Technical Improvements  Future research directions regarding the technical backbone of the CRAML framework should aim  to bolster the extrapolation stage of the pipeline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Embeddings can be utilized to improve the  transformation of context rules to datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' With embeddings added to the extrapolation method,  the need for training a ML classifier in the end may become obsolete.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  A second area of future work involves building up tools to aid the domain expert in the initial,  manual-driven stages of the CRAML process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Keyword extraction, topic modeling, automatic rule  induction, and knowledge graphs could all be useful tools to support the domain expert express his  or her worldview, as well as explore large text corpora in a richer way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Although the focus is currently placed on ML techniques, the role of more advanced classifiers  remains an open area of investigation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Deep Learning, in particular sequential models, could prove to  19  be powerful in boosting the predictive capability of models trained on CRAML-generated datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Of course, this would come with the added overhead of extra training and parameter tuning, which  must also be taken into account for future endeavors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Computational Social Science  CRAML is designed with flexibility and web-based sources of text in mind.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A plug-in was created  to integrate DocumentCloud (used by journalists and academics to post government documents)  for the project related to no poach agreements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' New plug-ins could draw data from web-based  sources of text such as Twitter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Niche ML classifiers built from user-data in a specific domain could  address content moderation challenges at scale [57, 62].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To address a concern in [101], government,  civil society, and non-governmental organizations could develop context rule sets to capture text  that is relevant to their interests and publish or license ML classifiers that provide useful feeds  and classifications of information tracking on topics of societal concern.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For academics, editors and  reviewers could demand greater transparency when claims are made about data built form text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Concerns with proprietary data sources and privacy can be partially addressed by the infor-  mation extraction methods used here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While additional efforts are needed, including the potential  development of further tools for differential privacy with text, the extraction process is a step to-  ward efforts to protect individuals against identification and protect the data owner from violation  of proprietary information and trade secrets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For example, researchers have been barred from ac-  cessing records due to privacy and confidentiality concerns, but with careful selection of keywords,  analysts could code chunks of extracted text and classify every document in a corpus without ever  accessing the full or confidential information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='12  Finally, researchers in the humanities and social scientists can hopefully develop diverse and  practical applications that uncover constructs and patterns currently “hidden” in unstructured  text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The CRAML framework and software tools can be used to analyze text in any language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To  the extent a construct is intra-subjectively reliable, it could be developed by a researcher into rules  and scaled over vast amounts of unstructured text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To the extent that inter-subjective variance is  high, we hope that by decreasing the time and effort needed to scale a framework, there will be many  opportunities for diverse voices to produce contesting interpretative schemes that are transparent  and replicable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  12For example, researchers could use CRAML software to track the 20th Century use of residential restrictive  covenants that barred Black, Jewish, Asian and other ethnic groups from living in certain neighborhoods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' County  commissioners of deeds have either barred researchers or severely limited access to digitized records due to concerns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For one project focused on Hennepin County, see https://mappingprejudice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='umn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='edu/.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  20  Acknowledgements  We are grateful for support from the Economic Security Project Anti-Monopoly Fund;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Loyola Rule  of Law Institute;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Loyola Quinlan School of Business;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and Loyola University Chicago.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' All errors are  the authors’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Conflict of interest  The authors have no conflicts of interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Supporting Information  See our Github repository for the full code base: https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='com/sjmeis/CRAML_Beta.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  21  References  [1]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Abbas et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Text analytics to support sense-making in social media: A language-action per-  spective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Publication Title: MIS Quarterly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' par.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [2]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Abbasi and H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Mis Quarterly (2008).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Publisher: JSTOR.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In:  Mis Quarterly (2010).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Chaos of Disciplines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' en.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' University of Chicago Press, Feb.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2001.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  isbn: 978-0-226-00101-2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [6]  Daron Acemoglu and David H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “Skills, Tasks and Technologies: Implications for Em-  ployment and Earnings”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Handbook of Labor Economics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Ed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' by Orley Ashenfelter and  David Card.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Elsevier, 2011, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 1043–1171.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='com/science/article/pii/S0169721811024105  (visited on 12/10/2012).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [7]  Amina Adadi and Mohammed Berrada.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Peeking Inside the Black-Box: A Survey on Ex-  plainable Artificial Intelligence (XAI)”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: IEEE Access 6 (2018), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 52138–52160.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [8]  Kiran Adnan and Rehan Akbar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: International Journal of Engi-  neering Business Management 11 (Jan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “A survey of text clustering algorithms”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In:  Mining text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Springer, 2012, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 77–128.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [11]  Clemens Apprich.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Secret Agents”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Digital Culture & Society 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1 (Mar.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2018), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 29–44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  doi: 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [12]  Alejandro Barredo Arrieta et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Explainable Artificial Intelligence (XAI): Concepts, Tax-  onomies, Opportunities and Challenges toward Responsible AI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='48550/ARXIV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  url: https://arxiv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='org/abs/1910.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [13]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Challenges of explaining the behavior of black-box AI systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “THE OPM DATA BREACH: AN INVESTIGATION OF SHARED EMO-  TIONAL REACTIONS ON TWITTER.” In: MIS Quarterly (2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Too Much to Know: Managing Scholarly Information before the Modern Age.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [25]  Nicholas Bloom and John Van Reenen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='4 (Nov.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [27]  Valerie C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Bradley et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Unrepresentative big surveys significantly overestimated US vac-  cine uptake”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' van den Broek, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “When the Machine Meets the Ex-  pert: An Ethnography of Developing AI for Hiring.” In: MIS Quarterly (2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Journal of Artificial Intelligence Research 70 (Jan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [34]  Aaron K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Chatterji et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Do ratings of firms converge?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Implications for managers, investors  and strategy researchers”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Strategic Management Journal 37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='8 (2016).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' ISBN: 0143-2095  Publisher: Wiley Online Library, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 1597–1614.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [35]  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Finding People with Emotional Distress in Online Social Media: A Design  Combining Machine Learning and Rule-Based Classification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' pweb.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [36]  Jaeho Choi, Anoop Menon, and Haris Tabakovic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Strategic Management Journal 42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9 (2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Allen, and Michael G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Endres.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Strategic Management Journal 42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' issn: 1097-  0266.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='5 (Sept.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' 1938–1963.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [40]  Lorrie F Cranor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [41]  Andrew D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Cutler et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Publisher:  SAGE Publications Inc, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  24  [42]  Alexander D’Amour et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Underspecification Presents Challenges for Credibility in Modern  Machine Learning”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: arXiv:2011.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [52]  Marion Fourcade.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “The Problem of Embodiment in the Sociology of Knowledge: After-  word to the Special Issue on Knowledge in Practice”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Qualitative Sociology 33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4  (Dec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' 569–574.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [53]  Andreas Geiger, Philip Lenz, and Raquel Urtasun.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' ISSN: 1063-6919.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' 3354–3361.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='1109/CVPR.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='6248074.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  25  [54]  Andreas Geiger, Philip Lenz, and Raquel Urtasun.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  the kitti vision benchmark suite”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: IEEE Conference on Computer Vision and Pattern  Recognition (CVPR) 2012.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' IEEE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2012, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Personnel Psychology 53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4 (2000).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Oestreicher-Singer, and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Saar-Tsechansky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [58]  Simona Giorgi, Massimo Maoret, and Edward J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='4  (May 14, 2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [59]  Barney G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Glaser and Anselm Strauss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The Discovery of Grounded Theory: Strategies for  Qualitative Research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Aldine Transaction, June 1967.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' isbn: 0-202-30260-1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [60]  Gary Goertz and James Mahoney.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A Tale of Two Cultures: Qualitative and Quantitative Re-  search in the Social Sciences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: Science Robotics  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='6 (Dec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [67]  Khodor Hammoud et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' In: CEUR Workshop  Proceedings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [68]  Eszter Hargittai.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Is Bigger Always Better?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Potential Biases of Big Data Derived from Social  Network Sites”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' en.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: The ANNALS of the American Academy of Political and Social Sci-  ence 659.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' Publisher: SAGE Publications Inc, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 63–76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [107]  Gunar Schirner et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “The future of human-in-the-loop cyber-physical systems”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Com-  puter 46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1 (2013), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [108]  Jeremy C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “More than words?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='4 (Oct.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  2008).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [110]  Jeremy C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' ISBN: 1094-4281 Publisher: Sage Publications Sage CA: Los Angeles, CA, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [111]  Yash Raj Shrestha et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Algorithm supported induction for building theory: How can we use  prediction models to theorize?”' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Organization Science 32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3 (May 1, 2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Number: 3 Pub-  lisher: INFORMS, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [112]  Wesley D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Sine, Arkangel M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Cordero, and Ryan S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Coles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Entrepreneurship through a uni-  fied sociological neoinstitutional lens”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [113]  Juan Luis Suárez et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Entrepreneurship Bias and the Mass Media: Evidence from Big  Data”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  30  [114]  M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Subramani et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Capability Development through Just-in-Time Access to Knowledge in  Document Repositories: A Longitudinal Examination of Technical Problem Solving.” In: MIS  Quarterly (2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “CONSTRUCTS AND INDICATORS: AN ONTOLOGICAL ANALYSIS.” In:  MIS Quarterly (2021).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' “Accelerating human-in-the-loop machine learning: Challenges and opportu-  nities”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Proceedings of the second workshop on data management for end-to-end machine  learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2018, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 1–4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  31  [129]  W.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Yue, Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Wang, and K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Hui.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “See no evil, hear no evil?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Dissecting the impact  of online hacker forums”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Mis Quarterly (2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Publisher: ink.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='  [130]  Fabio Massimo Zanzotto.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Human-in-the-loop artificial intelligence”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: Journal of Artificial  Intelligence Research 64 (2019), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 243–252.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  [131]  Zhewei Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “Addressing the Key Challenges of Developing Machine Learning AI  Systems for Knowledge-Intensive Work”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In: MIS Quarterly Executive 19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4 (Dec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Pub-  lisher: Association for Information Systems, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 221–238.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='direct=true&AuthType=ip,sso&db=bth&AN=147658492&scope=site&custid=s8448101  (visited on 11/03/2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  32  A  Appendix A: Using CRAML for a Literature Review  Bibliographic research often begins with search for relevant papers using an academic search engine,  but such search has a difficult time retrieving only the papers that use a specific empirical method  or type of data, for example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To find papers that illustrate the challenges CRAML was created to  address, we analyzed a corpus of all published papers from 5 top management journals from 2015-  2021 (Academy of Management Journal, Administrative Science Quarterly, Journal of International  Business Studies, Organization Science, and Strategic Management Journal).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We first assembled  the corpus and PDFs in Zotero, and then exported the metadata.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We converted all PDFs from  these journals to text, minimally cleaned the text (lower case, removing punctuation, replaced  abbreviations), and used CRAML software to find relevant papers using keywords, tags, and rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  We deductively generated list of tags and keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='json file contians the tags  and keywords used to extract all keyword-containing chunks of text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The context window was set  to 6 words, yielding chunks of text of a maximum length of 13 words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' After retrieving 13 word  chunks, we examined n-grams in CRAML and developed rules files for each tag in order to classify  the chunks that were relevant to our search.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The following headings present the rules files used  to classify which papers in the management literature contain relevant concepts - keywords alone  generated numerous false positives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We note that this effort could be much further refined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Given  the small size of the corpus and the variety of tags, machine learning was not desirable or attempted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  CRAML was highly useful to iteratively narrowing a search for relevant literature, and we stopped  when the results produced the relevant papers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As seen in the notes on the rule sets, keyword based  approaches alone are insufficient to narrowing accurately, and researchers can benefit from a process  of refinement that is context-aware and rule-based.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  “Is Text” rules: Papers drawing from Text Corpora  These rules that define the tag istext or “is text” identify papers that refer to a text corpus or  text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the first priority of rule-based classification, chunks containing the keywords “text”,  “repository”, “corpus”, and “document” are initially coded 0 (not istext).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The subsequent rule at  priority level 1 classifies all chunks containing the exact matching text (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “text analyis”) 1 (is  istext).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Given the istext rules, the resulting metadata will report the papers that discuss text data  and corpora equal to 1 for istext.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The most relevant papers were found when combining the istext  tag with additional tags described below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  33  Rule  Prio  istext  text  0  0  repository  0  0  corpus  0  0  document  0  0  text analysis  1  1  text corpus  1  1  textual corpus  1  1  text mine  1  1  text mining  1  1  prepared text  1  1  text based analys  1  1  text data  1  1  Figure 7: istext Rules  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ML rules  To find papers that discuss supervised learning, we construct the simple ML tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To make Figure  1, we focus only on observations where istext and ML are both equal to 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Rule  Prio  ML  learning  0  0  supervised learning  1  1  machine learning  1  1  deep learning  1  1  Figure 8: ML Rules  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  NLP Rules  We follow the same structure for the NLP tag for finding papers that use NLP.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For NLP, we also  use regular expressions to find any chunk containing mention of the term “embedding” and one or  more of “word”, “text”, or “language.”  Rule  Prio  NLP  nlp  0  1  natural language process  0  1  REGEX :::(?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content=' = .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='∗\\bword\\b)|(?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' = .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='∗  1  1  Figure 9: NLP Rules  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4  Proprietary rules  The keywords for proprietary data and models and the proprietary tag extracted a large number  of irrelevant chunks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To limit the focus to non-transparency in data and models, we use regular  expressions to combine our base priority keywords with the added terms “data” or “model” to  capture the papers that use or refer to proprietary data or models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  34  Rule  Prio  proprietary  confidential  0  0  license  0  0  sensitive  0  0  proprietary  0  0  secret  0  0  REGEX :::(?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='∗  1  1  Figure 10: Proprietary Rules  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='5  Topic Modeling Rules  For the topic modeling tag topic_model, we look for papers with chunks of text that refer to  unsupervised learning, Latent Dirichlet Allocation (LDA), and topic models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Rule  Prio  topic_model  unsupervised  0  0  unsupervised learning  1  1  lda  1  1  topic model  1  1  latent dirichlet allocation  1  1  Figure 11: Topic Model Rules  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6  AI Rules  For the tag AI, we look for papers with chunks of text that refer to artificial intelligence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Rule  Prio  AI  artificial  0  0  ai  1  1  artificially intelligen  1  1  artificial intelligen  1  1  neural network  1  1  Figure 12: AI Rules  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='7  The Results  CRAML’s extrapolate function yields a CSV file.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Each row is a paper, and each column contains  the metadata attributes of the paper (authors year, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=') and each tag constructed in CRAML.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  For each paper, CRAML provides a 0/1 indicator of whether or not the paper contains a chunk  corresponding to the rules files above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Here, we present a table that aggregates the result of the  CRAML analysis by year and theme:  Because we are interested in particular in papers that use text corpora, to make the graph in  Figure 1 and conduct our literature review, we filtered the metadata for only the papers that equal  1 for istext.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' CRAML allowed us to find “needles” in a “haystack” of publications, narrowing our  search of the literature, allowing us to more closely examine the plausibly relevant papers, and read  and incorporate relevant papers into our literature review.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The data for Figure 1 that highlights  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='the discussion of various text analysis techniques within these papers is presented below:  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='35  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Year  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Proprietary  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Data  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='or  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Models  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Topic  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Models  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='or  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='LDA  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='ML  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='NLP  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='AI  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='CATA  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Text or  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Docu-  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='ment  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Corpus  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2015  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='19  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='53  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2016  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='11  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='68  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='10  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2017  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='18  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='69  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2018  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='20  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='73  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='17  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2019  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='13  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='82  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='18  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2020  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='17  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='67  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='18  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2021  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='19  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='7  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='80  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='Table 1: Total Papers by Year that Reflect Rule Sets  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Year  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Proprietary  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Data  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='or  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Models  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Topic  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Models  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='or  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='LDA  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='ML  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='NLP  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='AI  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='CATA  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Text or  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Docu-  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='ment  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Corpus  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2015  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='4  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+page_content='6  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='19  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='31  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Table 2: Subset of Papers Where istext=1 by Year  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='36  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='B  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Appendix B: Using CRAML to Build Classifiers from  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Job Advertisement Text  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='One advantage of CRAML is that a classifier can be trained and validated using proprietary infor-  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='mation but can be made available to other academic researchers for transparency,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' validation,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and  replication while preserving underlying proprietary information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To illustrate, we describe and pub-  lish nine classifiers from job advertisement text and outline our process for building and validating  these.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We describe a process for building open source research datasets drawn from proprietary text  data with transparent rules and discuss a growing research ecosystem to develop useful classifiers  drawn from the text of job advertisements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Building and Publishing New Classifiers from Job Ad Text  Below, we describe the construction and performance of classifiers already constructed using job  advertisement text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The following variables are constructed from a random forest ML algorithm  that classifies each job advertisement 0/1 on a particular variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' These variables are otherwise  coded 0, but are equal to 1 if the job advertisement indicates:  Work From Home.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job with the opportunity to work-from-home, including both full-time  and hybrid work-from-home jobs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Independent Contractor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A 1099 independent contractor job.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Professional License Required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job requiring a professional license or formal apprenticeship.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Union Presence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job within a collective bargaining unit or a job that involves negotiating  and working with unions (labor relations jobs, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Citizenship Required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job where the holder must be a U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' citizen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Work Authorization Required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job where the job holder must be legally authorized to work  in the U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Visa Inclusivity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job for which a firm is willing to sponsor a visa-holder for the position.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Visa Exclusivity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job for which a firm is not willing to sponsor a visa-holder for the position.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  EOE/AA Statement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A job ad that contains EOE/AA statement is present.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In building each classifier, close attention was paid to building reliable and valid measures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To  construct each variable listed above, the 6 words before and after every appearance of a “keyword”  (in column 2) of Table 3 were extracted from the text corpus of job advertisements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Research assistants and one lead researcher hand-coded a sample of the most frequently occurring  13-word “text chunks” 0 or 1 for each variable we wanted in the finished dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Based upon the  hand-coded sample, context rules were initially drafted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Table 4 illustrates the hand-coding and  manual validation process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For the work from home variable, independent hand-coding generated  1,524 increasingly lengthy context rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Following extrapolation to a training dataset drawn from  a random sample, RAs performed an additional round of independent hand-coding to arrive at  a total of 2,901 hand-coded chunks for the work from home variable that are matched to the  training dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Comparing known “true positives” via hand-coding and known “true negatives”  37  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Variable  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Keyword(s)  Work From Home  “home",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “remote",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “telecommut",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “telework",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “virtual",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “videocon-  ferenc",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “internet",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “anywhere"  Independent Contractor  “contract”  Professional  License  Re-  quired  “licens",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “credential",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “certifi",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “apprentice"  Union Presence  “collective",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “bargain",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “contract",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “union"  Government Contractor  “affirmative",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “opportunity",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “eoe",' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “contract"  Citizenship Required  “citizen”  Work  Authorization  Re-  quired  “authoriz”  Visa Inclusive  “visa”,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “1b”  Visa Exclusive  “visa”,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' “1b”  Table 3: Keywords for Initial Classifiers Built  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Variable  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Hand-coded Chunks  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' ML Sample N Matched  with Hand-Coding  Work From Home  2,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='901  15,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='297  Independent Contractor  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='287  8,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='771  Professional  License  Re-  quired  11,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='107  15,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='665  Union Presence  5,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='357  14,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='254  Government Contractor  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='427  19,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='564  Citizenship Required  418  242  Work  Authorization  Re-  quired  890  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='888  Visa Inclusive  6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='796  3,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='660  Visa Exclusive  6,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='764  1,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='613  Table 4: Hand-coding and Matched ML Sample for Initial Classifiers Built  from hand-coding to the training dataset,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' we are confident that the training dataset classifies at  least 15,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='297 work from home chunks correctly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Because the process begins by feeding the training  dataset all chunks containing the keywords, most chunks in the training dataset are equal to 0,  and include many chunks containing irrelevant uses of the word “home”: “homework tutor”, “home  healthcare”, and “homeland security”, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=', all contain the keyword “home” after processing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This  “negative sampling” of chunks is crucial for training ML models to distinguish between a 0 and 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Because the focus is accuracy, or correctly identifying work from home jobs with a 1, it is possible  that recall suffers, as this process misses isolated instances of work from home jobs with highly  unusual text patterns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Once a strategic sample of the training dataset provides a perfect match with the hand-coded  data, we use the training dataset to train a ML model that predicts, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=', if a given job is work-  from-home.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' We tested logistic regression, naïve Bayes, and random forest models, and found that  random forests perform best.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Table 5 presents the size of a strategically selected sample of ML  results used to assess accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This sample size varies for each variable, as each variable occurs  38  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Variable  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  % of ML Sample Con-  firmed True Positives  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' F1 Score  Work From Home  92.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='976  Independent Contractor  98.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='994  Professional  License  Re-  quired  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='5%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='890  Union Presence  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='874  Government Contractor  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='996  Citizenship Required  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='976  Work  Authorization  Re-  quired  97%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='994  Visa Inclusive  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='890  Visa Exclusive  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0%  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='874  Table 5: Percent of True Positives Confirmed by Hand-Matching and F-1 Scores  with different frequency in the raw data, and while initially drawn from a random sample of chunks  containing the keywords, it is not random, but oversamples the most frequently occurring “positive”  chunks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Sample size needed to validate varies by the complexity of the rules needed to capture variation  in the chunks that contain the keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For some variables, a large sample is necessary because of  subtle variations in the text: there are many ways to indicate a “work from home” job, and as such,  there are many keywords and many different types of chunks that contain the keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In complex  cases, a domain expert must elaborate many rules to capture the variation in the text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For other  variables, such as “citizenship required,” among chunks containing the keyword “citizen,” there is  little variation in the text and only 63 context rules are required to handle the classification scheme  envisioned.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A smaller sample is acceptable in such cases because the frequency of key chunks in the  sample of chunks are relatively large: correctly classifying the chunk “citizenship is required” 1 and  almost everything else in the sample 0 captures most of the nuance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A very high proportion of the  percentages in Column 2 of Table 5 not known to be true positives are true negatives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The percent of known true positives in column 2 of Table 5 is based upon exact matches between  hand-coded chunks and the results of a sample of ML tagged chunks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Finally, to assess the accuracy  of the ML algorithm, column 3 reports the F-1 score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  While “work from home” is an omnibus measure of whether a job-holder can work from home,  we earlier abandoned work on potential refinements such as hybrid work field jobs that permit work  from home.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Each step in this process has the potential for mistakes to slip into the classification  process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' While the ultimate validity rests on the opinion of other experts, the hand-coded files, the  software, and large samples of text chunks can be published to encourage others’ efforts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The data  and software transparency will allow others to make their own models following their own process  and could lead to better classifications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In the process described above, we paid additional attention to qualifiers: words that have the  ability to change the meaning of a text chunk in a significant manner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Keep words are just that –  words that should be kept, even though they exist in a region to be trimmed away.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  39  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Building Open Source Datasets  The framework adopted and the CRAML software tool facilitates a pipeline for storing all (merged)  classification output to a database of choice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In this particular application with the data mentioned  here, a simple relational SQLite database with the following schema was used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  id INTEGER PRIMARY KEY  year INTEGER  month INTEGER  soc REAL  onet REAL  employer TEXT  sector REAL  fips TEXT  title TEXT  Figure 13: Example Database Schema (for Jobs)  Using this schema, a jobs database was created where the novel, complete, merged, and classified  dataset is stored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' An example snippet of this database’s contents is shown in Figure 14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  id  vendor  effective-date  nopoach  app-7653  DHH Group Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  3/24/2017  1  app-15957  Apogee Learning LLC  9/20/2019  1  app-1853  The Agency Real Estate Franchising LLC  4/3/2015  1  app-7888  Winmark Corporation (Once Upon A Child)  3/28/2017  1  app-18366  Atomium Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  6/25/2020  1  app-23189  Vision Source LLC  3/11/2022  0  app-22302  Brinker International Payroll Company L P (Chili’s)  11/1/2021  0  468744  Annex Brands Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  1/17/2013  0  app-14481  Gokhale Method Institute Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  4/11/2019  1  app-14643  Pizza Guys Franchises Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  7/22/2019  0  Figure 14: Random Sample from Jobs Database  Note that much of the data from the meta-data was left out for readability and for anonymiza-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The tag names have also been abbreviated, but they follow the same order as listed in  Section B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In essence, these tag columns represent the codification of the original text data into  a structured dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This dataset, in turn, can be used for further research and analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Growing an Ecosystem for Labor Market Research from Text  The pipeline outlined above regarding the ML models and rule sets we released can be scaled  and other researchers can build their own text to data classifiers of job advertisements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  NLx  Research Hub data is proprietary and licensed to academic users for academic use, as well as  state workforce agencies for research purposes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Access to the full corpus of job advertisements and  the associated metadata requires an application and compliance with a (free) licensing agreement  in order to protect sensitive information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  However, releasing de-identified extracts of keyword-  containing chunks of the text of job ads could be both fair use and encourage a community of  40  academic researchers and citizens to develop ML classifiers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such text chunks, and not the full  corpus, are all that is needed to build a niche classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The process of constructing a ML classifier  could be done entirely in CRAML without ever needing access to sensitive information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Once built, if licensed for non-commercial academic use, scholars who obtain permission to access  the underlying full text can use ML classifiers on the full text corpus and produce new open-source  research datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Certain forms of data aggregation pose little risk: for example, occupation, state,  commuting zone, and yearly summary data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' With respect to firm-level data, aggregation is possible  when exercising judgement to ensure no recent sensitive matters are publicly released (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' recent  recruitment efforts that indicate adoption of a particular business strategy that might affect market  valuation or competitors’ strategy).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  41  C  Appendix C: The CRAML Pipeline  This appendix describes the CRAML methodology in detail with illustrations from the worked  example introduced in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Extraction Algorithm  In Algorithm 1, we present the algorithm to extract context windows from a set of text documents,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' a corpus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This represents the important first step for handling large-scale unstructured text  corpora by first extracting the “candidate diamonds” from the rough, in order to allow for the  precise analysis of a domain expert.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Algorithm 1 Extraction Algorithm  Require: Text: collection of text documents,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Keywords: list of defined keywords  Ensure: list of extracted files (location)  1: all_contexts = {}  2: for raw_text in documents do  ⊲ Note: done in parallel (unordered)  3:  contexts = []  4:  id = generate id  5:  if any keyword in text then  6:  cleaned = clean(text)  ⊲ text replace and regex cleaning  7:  for sentence in cleaned do  8:  if any keyword in sentence then  9:  c = get_context(sentence)  ⊲ get context window  10:  contexts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append(c)  11:  contexts = set(contexts)  12:  all_contexts[id] = contexts  13: df = pd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='DataFrame(all_contexts)  14: df.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='to_csv()  15: return list of saved filenames  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Keywords  As displayed in Algorithm 1, a list of defined keywords is required for extraction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The extraction  algorithm will extract any chunk of text where one of the keywords appears, and store the chunk  and metadata about its location in the corpus inside a CSV file for human analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Users must  define a list of keywords for each tag, which are given further elaboration in Section C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Note that the extraction algorithm pulls all chunks where keywords are exact matched to a  string of text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For example, the keyword “employ” will extract all of the variants that contain that  exact keyword (employment, employer, employee, unemployment, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  The Output  The result of running Algorithm 1 is a CSV formatted dataset containing chunks of text, with  a minimum of two fields: id and text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Note that additional fields may also be included.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The  ID matches the identification number from the original data, and text represents a delimited list  42  of context windows around extracted keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In this case, a context window with a defined  parameter n refers the an extracted chunk of text with a maximum of n words to the right and left  of the keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If a punctuation mark is reached before n, then the context window will be shorter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Thus, with a n of 12, context windows are a maximum of 25 word chunks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Context windows can  be selected as either words or sentences;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' ie, a user can extract all keyword-containing sentences and  the n sentences to the left and right of a keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A sample from one extracted CSV file in Table  6 illustrates this, with firm names changed:  id  firm  text  10D4977B-000  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 1  {you shall not hire or permit .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='}  ADSPO15-0807  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2  {will not hire an applicant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='}  CHR21009-CHS  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 3  {a contractor shall not employ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='.}  99999-001  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 4  {non solicitation agreements with .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='}  Table 6: Illustrative extracted context windows with fictional company names  Note that for display purposes, only outputs relatively short in length were chosen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' It is often  the case that the extracted “text” is much longer in length, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' many contexts are extracted per  contract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The output of the extract algorithm is an “intermediate” dataset of (ID, text) tuples,  where the text is simply a long, ’|’ delimited string of all the extracted context windows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Looking  at the example shown, one can see that in each extracted chunk of text, a keyword is present, along  with its extracted context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='4  N-gram Exploration  The first step towards building up rule sets is having all of the plausibly relevant text extracted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The exploration of n-gram structures within the extracted data ensures that the context window is  correct, and if so, serves as a first step for construction of rules described in the following section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  This is accomplished with the algorithm presented in Algorithm 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The result with a given n is  the a file with the enumerated occurrences of each relevant n-gram, sorted in descending order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Algorithm 2 N-gram Exploration  Require: Parent Directory: where the extracted CSVs are located, n: desired n-gram size  Ensure: file with enumerated n-grams  1: global_counts = {}  2: for file in parent directory do  3:  for row text in file do  4:  split = text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='split(’|’)  5:  for chunk in split do  6:  length = len(chunk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='split())  7:  rules = chunk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='split()[max(0, length/2 - n), min(length, length/2 + n)]  8:  global_counts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='update(Counter(rules))  9: return global_counts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='to_csv()  43  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='5  Rule Creation: Building the Bridge  From the previous step, a researcher is now enabled to obtain a general picture of what context  windows appear with the unstructured text data, as well as their relative occurrences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Using this,  the researcher follows two decision processes: (1) the creation of a tag set, and subsequently (2) the  creation of a rule set for each tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Both sets are defined below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Tags  A tag is a title given to a certain characteristic of a particular document.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' These tags can be  easily and simply defined, and are binary in nature, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 1 if true or 0 if not true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The collection of  defined tags make up the tag set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Each tag in the tag set is assigned either 1 or 0 for every unique  document (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' unique ID) in the original data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Specifically for the franchise document example,  the following tag is defined:  nopoach – a non-solicitation clause that prohibits one franchise from recruiting workers from  the another franchise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  With this framework, one can define an arbitrary amount of tags;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' furthermore, exactly what  these tags mean, ie.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' what definition they take on, is entirely up to the researcher.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Binary classifi-  cations can be further broken down by defining additional “sub-tags”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As demonstrated below, an  examination of the context surrounding non-solicitation suggests further tags for future research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  At the data analysis stage, these can be combined to create new measurements of concepts involving  multiple tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Crucially, the meaning that is assumed by each tag is defined via its rule set, which  is discussed next.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  nopoach_nohire – a no poach clause that includes a no hire clause.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  noncompete – an employee non-compete clause.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  jurisdiction – language that limits the application of a no poach or non-compete to certain  jurisdictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  narrow – language that limits the application of a no poach or non-compete to certain em-  ployees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  no_nopoach – language that limits the use of no poach or non-compete clauses - stating that  these clauses are not enforceable against employees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Rules  For each given tag, a researcher will now define a list of rules that encompasses the definition  and characteristics of this tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' More concretely, a rule is a chunk of any number of words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Therefore,  a rule can be a single word, or even an entire sentence (up to the maximum length of the extracted  chunks, here 25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A single rule set, defined within a corresponding file, can contain one or more  tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If more than one tag is contained within a rule set, this means that the tags that are bundled  together are related enough such that some rules more overlap, or some rules may define one tag,  while precluding the other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For each tag contained within a rule set, this tag is defined for each  given rule, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' is assigned either 1 or 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Finally, every rule in all rule sets must be assigned a  priority (“prio”), which indicates its relative order of operation compared to other rules within the  same rule set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' An example excerpt from a rule file is given in Table 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Priority is important in the sense that it defines a hierarchy of how text chunks might be  assigned certain tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' From the above example, one starts with every chunk containing “hire” to  be nopoach=0 at prio=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' When, however, one encounters “may not hire” within a piece of text,  this then is a plausible indicator that nopoach=1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If a text chunk contains “may not hire” – the  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='44  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='rule  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='prio  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='nopoach  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='hire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='shall not hire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='will not hire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='may not hire  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='you shall not hire or permit any third party or outside vendors to access or perform any service  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='may not hire an applicant who has a felony  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='will not hire any person regardless of medical marijuana card  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='shall not hire or promote anyone who may have contact with residents  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='not hire offer to hire or otherwise solicit any employee  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Table 7: Excerpt from the rule set of the nopoach tag in formative stages  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='subsequent rule “may not hire” assigned priority prio=1 proceeds to classify it with nopoach=1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Upon examination, that rule turns out to have exceptions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Moving on to a higher priority rule,  prio=2 can create exceptions to prio=1 rules: for example, with prio=2, a rule that states “may  not hire an applicant who has a felony” overwrites the previous tag allocation, now assigning text  chunks containing the string of text in the rule to nopoach=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In this way, priority is important to  handling iterative coding work and possibly overlapping or contradicting rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The final important aspect of rule creation comes with the use of Regular Expressions, denoted  by rules with the “REGEX:::” qualifier prepended to the regular expression itself.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Instead of simple  text matching for a rule, regex rules will instead check to verify if a particular text chunk satisfies  the regular expression or not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Their usage allows for generalization, in situations where contexts  are variable in length and content, yet possess the same general meaning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Once the researcher feels that the rule set is saturated, it is important to “prune” rules and  validate them through repeated extrapolation and adjustment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Context windows should be no  longer than the longest rule, which should be no longer than necessary to precisely capture the tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The final rule sets used in the franchise document analysis are available online.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='6  Extrapolation: Crossing the Bridge  With this collection of rule sets (for all defined tags) in hand, a tool is now needed to translate the  rules contained within to a workable dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such a tool is useful because it takes the manually  coded context rules as input, and it then proceeds to “extrapolate” them into a training dataset  from either a selected subset of extracted data files or the full dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Thus, we can cross the bridge  from expert-created rules to structured, annotated datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The Subset  As mentioned, the extrapolation algorithm can operate on a selected subset of the  entirety of the data, so as to create a representative training set, from which a robust, accurate  classifier can be trained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This is accomplished by randomly and uniformly selecting documents  from the original text files.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the case where a model will not be learned, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' where only the  extrapolated dataset is desired, performing this sampling is not necessary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The Extrapolation Algorithm  The algorithm used to create a training data set for each tag  is now defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Note that this algorithm is run per tag, meaning that the eventual output is a  training set for each tag, which will then be used to train a classifier for each tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The algorithm  pseudocode is outlined in Algorithm 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  45  Algorithm 3 Extrapolation Algorithm  Require: Parent Directory: where the subset CSV files are located, Rules File: a rule set for  a given tag or tags, s: sampling rate, do_neg: whether to perform negative sampling  Ensure: training data set for given tag(s)  1: results = []  2: for file f in subset do  3:  data = read_csv(f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='sample(s)  ⊲ sample desired fraction of data  4:  for text in data do  ⊲ each ’|’ delimted extracted line  5:  for rule r in rule set do  6:  match = []  7:  plus = 0  ⊲ for negative sampling only  8:  for x in text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='split(’|’) do  9:  if ’REGEX’ in r then  10:  if regex.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='search(r, x) then  11:  match.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append((x,1))  12:  plus += 1  13:  else if plus > 0 and do_neg == True then  14:  if not any ru in x for ru in rule set then  15:  match.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append((x,0))  16:  plus -= len(tags)  ⊲ i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' number of tags in rule set  17:  else  18:  if r in x then  19:  match.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append((x,1))  20:  plus += 1  21:  else if plus > 0 and do_neg == True then  22:  if not any ru in x for ru in rule set then  23:  match.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append((x,0))  24:  plus -= len(tags)  25:  random.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='shuffle(match)  26:  for m in match do  ⊲ m[0] = text, m[1] = negative sample?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  27:  results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append(text chunk, rule, priority-weighted length, tag encoding)  28: training = DataFrame(results)  29: training = training.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='sort(priority-weighted length).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='drop_duplicates(chunk)  30: return training as CSV  One important note about the extraction algorithm is the sampling rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Since many files are  included in the subset, running extrapolation on the entirety of this subset would result in quite  large training datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To avoid this, only a random sampling of each subset file is taken, in order  to ensure a manageable training dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Secondly, the concept of negative sampling is incorporated  into the algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Such a concept allows for “negative”, non-keyword containing text chunks also  to be included in the training data, in the case that a classifier that can discriminate between  keyword- and non-keyword-containing instances is desired.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Ultimately, the main purpose of the extrapolation algorithm is to bridge the human-centric rule  creation phase with the ensuing model training and classification stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Concretely, the manually  created rule sets that are the product of the former are converted to large, yet workable training  data sets that are vital to the functioning of the latter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Thus, this transition from defined rule sets  46  to classifier training is facilitated by such an extrapolation method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  As described above, a user may need to augment the training data produced from CRAML in  order to improve model performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Poorly performing models may reflect that the underlying  tags are not well-defined, and need additional refinement, or simply that there are not enough  positive or negative cases in the corpus to build a reliable classification model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='7  Baseline Testing Cycle: Boosting Real-World Applicability  After an initial extrapolation, the expert engages in iterative testing to revise the rules to achieve  a comprehensive and accurately coded dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The expert does this with output from the extrap-  olation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' An excerpt (shortened for readability) of the nopoach rules is provided in Table 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='id  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='chunk  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='rule  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='nopoach  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='527557  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='shall not recruit or hire any employee or former employee offranchisor or any  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='shall not recruit  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='781133  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='of offenders page of monitoring center staff vendors shall not employ felons in  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='shall not employ felons  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='272571  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='in item ahove you may not solicit customers from outside your territory without  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='may not solicit customers  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='487216  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='or our designee you will not hire third party or outside vendors to  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='you will not hire third party or outside vendors  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='0  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='792020  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='franchise lyou may not recruit or hire any employee or former employee of  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='may not recruit  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='714298  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='non solicitation of employees employee agrees that during  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='non solicitation of employees  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='Table 8: Some entries from the novel training data created for nopoach during testing  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='As can be seen,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' the extrapolated training data files contain the extracted text chunks,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' which  rule “caught” the particular chunk,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' and finally the appropriate tag value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This file can be reviewed  by the user to determine if the rules are working as intended.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' A sample of chunks that oversamples  positive tags (=1) and provides a minimum number of cases per rule can also be sent at this point  for blind review by third-party coders to validate and ensure inter-subject reliability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In the Table 8 example, early rules such as “shall not recruit”, “shall not employ”, and “shall  not hire” were later abandoned due to the multiple exceptions to these rules as seen in the Table.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Instead, discrete statements that clearly stated that an employee shall not be recruited or solicited  or hired were tagged nopoach=1  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='8  Validation: Involving Third-Party Independent Coders  Validation helps to ensure inter-rater reliability, accuracy, and precision.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Involving third-parties at  the stage at which rule sets are producing seemingly reliable results tests whether the tags are well-  enough defined to be agreed to by third parties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The researcher gives an independent coder only  a description of the desired tag, the text chunks, and deletes the rules and the CRAML-generated  coding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The independent coder completes their review, and the researcher compares the results  of the rule-set produced coding with the independent coder’s coding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' All discrepancies should be  reconciled before proceeding further.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Based upon the performance displayed by this last step in the process, or by an externally  imposed requirement to repeat the process, the researcher can choose to revisit the tags and rule  sets, once again performing an exploration to search for more representative rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' It is important  to emphasize the necessity of judgement in this phase, as the decision to repeat this process is  a subjective one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Incorporating hand-coding by independent research assistants can help greatly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Moreover, the encoding, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' tag values, given to each particular rule must come from knowledgeable,  grounded reasoning, especially in cases where certain keywords serve different meanings in possibly  very disparate contexts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Therefore, it is in this cycle where the most manual effort is required, but  also where the crucial foundation to the rest of the framework is built.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  47  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9  Model Training and Classification: Datasets in Action  The final stage in the proposed framework is the classification itself, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' the mapping of a particular  text chunk to its corresponding tag set encoding (0/1 for each tag).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In order to accomplish this,  classification models must be learned from the rule sets discussed in the previous section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This  process is now outlined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The presence of context rules alone are not sufficient in the sense that they represent high  precision classification rules that will always detect exactly what is described by the rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The  next step of using a classifier is to learn a model that not only detects these “simple” cases that can  be caught by string matching or regular expressions, but rather one that can also learn in which  general contexts keywords appear which cause a certain tag to be true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This, therefore, motivates  the need for comprehensive training data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The final step in the testing cycle involves the training of a baseline classifier to test the per-  formance of this classifier on an unseen test set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In this case, a simple Naive Bayes classifier was  chosen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' First, training instances are converted to TF-IDF vectors (introduced in more detail later),  and then a Naive Bayes classifier is trained for each tag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Finally, output metrics are displayed,  namely Accuracy, Precision, Recall, and F1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Using these metrics, a researcher can (roughly) evalu-  ate the current performance of the classifier, which indicates the strength (“representativeness”) of  the underlying training data, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' rules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='1  Flexibility in Machine Learning Methods  An important step towards the building of a general-purpose classification system was model selec-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In particular, it becomes the task to identify the Machine Learning method best suited for  the multi-label, binary classification task at hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Crucial to note is this multi-label aspect, as it is  certainly possible for a single document to have more than one tag attribute be present.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As such,  multiple candidates for classification models were chosen, all of which could handle this multi-label  binary classification task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' So far, only “shallow” Machine Learning models were tested.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The methods included:  Naive Bayes – also used as the baseline classification method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Simple probabilistic classifiers  using Bayes’ theorem as a backbone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Relatively easy and efficient to train.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Logistic Regression – classification technique utilizing the logistic function (and a classifi-  cation threshold) to predict the value of a dependent variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Stochastic Gradient Descent Classification – a misnomer in the sense that SGD does  not actually perform the classification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Rather, SGD is used to optimize a linear model, in  this case a Support Vector Machine.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Random Forest – a classifier using an ensemble of Decision Trees.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In a test of the various methods on a sample classification task (for the nopoach tag), the  classifiers performed as described in Table 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In the case of large text corpora, particular in the example of no poach clauses in state contracts,  it may be the case that the positive cases, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' where a tag is assigned 1, are in the minority.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As a  result, the accuracy score becomes somewhat less important.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' More meaningful are the precision and  recall scores.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Essentially, precision measures the percentage of correctly identified positive cases,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' how many of the classified ’1’s are indeed truly positive cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Recall measures that percentage  of correctly identified positive cases among all positive cases in the true labels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Together, these two  metrics can be succinctly summarized in the F1-score, which is the harmonic mean of the two.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  48  Acc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Precision  Recall  F1  Naive Bayes  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='93  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='60  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='95  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='74  Logistic Regression  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='99  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='91  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='96  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='94  SGD SVM  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='98  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='91  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='92  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='92  Random Forest  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='99  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='97  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='96  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='97  Table 9: Performance of various ML classifiers  As can be observed from Table 9, the Random Forest model shows superior performance with  regards to all metrics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The same outcome was observed across the board with various rule sets,  or rather their corresponding training data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As a result, the Random Forest was chosen to be the  classification method of choice for the purposes of this dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  With the respect to the general-purpose nature of this text classification framework, it is impor-  tant to emphasize that the choice of classification method here will not necessarily be the optimal  choice for other applications.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In addition to this, the utilization of more advanced and powerful  methods could certainly prove to be beneficial, and this remains a topic for future research.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In  the end, though, the framework allows for essentially any model to be used, as long as it can be  properly stored and loaded for use in the process pipeline.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  As part of the CRAML framework, the task of choosing a specific model is left to the user.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This  make sense due to the fact that different data, different domains, and different desired outcomes  may require different models to be chosen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the end, the focus of CRAML on the data creation  process allows for a flexibility in the choice of model to train on this data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Further details on this  process can be found in the CRAML documentation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='2  Outline of Model Training  In order to adapt the use of classification models such as Random Forests for the classification of  novel text datasets such as the one described throughout the previous sections, some considerations  must be made.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' They are described below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  TF-IDF is utilized to convert a database of unstructured text entities into a matrix of numerically-  valued vectors.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Concretely, for a dataset containing n documents and a vocabulary of m words, the  resulting TF-IDF matrix is n x m in dimension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Through this vectorization of text, models can be  trained and classification can now be performed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  As a point for future work, the utilization of more advanced (and potentially meaningful) text  representations could lead to richer training data for the proposed CRAML framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Training - Grid Search  With the training of ML models comes many tuneable parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In  order to optimize the resulting classifier for each tag, a tuning stage was added into the framework,  which determines the optimal parameters, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' for a Random Forest, given a particular dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Here it is important to emphasize the significance of this stage in the overall framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' As all  potential incoming datasets may be different in nature, different parameter values may be needed  to achieve the best performance possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In order to best support the general-purpose nature of  the proposed framework, performing fine-tuning of parameters is crucial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Training - Purification  As a final step to creating the classifiers for each tag, a purification  process was run on the trained models, in order to reduce size, and as a result, classification time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  This was accomplished via an available library, which eliminates unneeded dependencies and in the  49  case of Random Forests, prunes the trees according to certain criteria.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The effects of this process  were quite dramatic, reducing most models to at least half the size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The potential complexity of  Random Forests, and thus the need for the purification process, is visualized in Figure 15, which  display a pre-purification decision tree.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Figure 15: One of the decisions trees within the nopoach Random Forest  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='3  Classifier Integration  Once a model for each tag is trained, it is then stored in pickle format, so that it can be later loaded  and utilized within the framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' To do this, the user must manually enter the filename of each  saved model into a JSON formatted file, which maps each tag to its corresponding classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  50  丰Note how these tags match up with the mapping of tags to manually defined keywords.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The  naming convention used for the saved models was to specify the method used, the tag to be classified,  the achieved F1-score, and the use of purification or not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  A significant decision that was made along the design process of the framework was whether  to utilize the negative sampling scheme that was left as an option in the extrapolation process  (Algorithm 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This decision would most directly affect the function of the classifiers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' More con-  cretely, without negative sampling, the classifier for each tag would be to “classify a tag as 0 or 1,  provided that the chunk to be classified contains a tag-defined keyword”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' On the other hand, per-  forming the the negative sampling process introduces random, non-keyword-containing text chunks  into the model training process, thereby learning these instances into the given model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Here, the  classification task becomes “classify any given piece of text as 0 or 1, regardless of its content”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  With these two approaches in mind, it was ultimately decided to implement the former, thereby  only advancing a text chunk to the classification stage if it indeed contained a keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' If not,  the classification was automatically made to be 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' It is quite important to stress that this design  decision was made knowing the makeup of the textual data, as well as the characteristics of the  tags to be classified.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the end, in order for a tag to be assigned a 1, a necessary condition is for  it to contain a tag-specific keyword.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Otherwise, it is not possible to obtain the classification of 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The classification process, therefore, is in place to “weed out” keyword-containing text chunks that  actually do not lead to the desired tag attribute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In other domains, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' with other text datasets  created via this framework, this line of reasoning may not hold absolutely, and an argument could  be made for the use of negative sampling.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In this way, it is once again paramount for (a team of)  researchers to define their tags thoroughly and explore the makeup of the underlying data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  One final component is the option of a preprocessing step for each classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' The motivation  is that in the text chunks, which are relatively large in length compared to the single keyword  within, there might exist much information, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' words, that do not play a role in a particular tag  at hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Particularly with tags in which the pertinent information sits close to the keyword, any  other irrelevant information will only serve to confuse the learning of a classification model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' With  this in mind, the proposed preprocessing step will serve to “trim” the left and right ends of a given  text chunk, thus reducing the amount of text noise within this chunk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In this process, though, two  considerations must be made.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Firstly, if certain qualifier words, such as negations, exists within  the regions to be trimmed, this could potentially be vital information lost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Secondly, there may be  specific known words or phrases that appear that usually appear in the proximity of a keyword,  yet might also be trimmed away.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' For these reasons, two more mappings, following the structure of  previous ones where an entry exists for each tag, are defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Qualifiers involves the words that  have the ability to change the meaning of a text chunk in a signficant manner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Keep words are just  that – words that should be kept, even though they exist in a region to be trimmed away.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  With these definitions and the preprocessing steps, the pseudocode is outlined in Algorithm 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  In the testing with this preprocessing stage, the TRIM parameter was chosen to be 2, resulting  in chunks of length 5, not including possibly kept words.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In the end, this stage was excluded from  the framework in the context of the job posting data, for with many tags there was actually an  observed decline in classification performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This sheds light on the importance of relatively  faraway context words from the main keyword for many of the tags.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Again, this may differ with  other datasets, so testing with this preprocessing stage is recommended.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  51  Algorithm 4 Preprocessing Algorithm  Require: Training CSV: file that contains the training data to be trimmed,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Tags: tags to be  processed,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Qualifiers: for each tag,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' Keeps: for each tag,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' TRIM: target context size  Ensure: trimmed training data  1: new_data = []  2: for text in training data do  3:  index = get_index(text)  ⊲ get index of keyword within chunk  4:  for q in Qualifiers do  5:  found = search_for(q,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' text)  ⊲ find qualifiers in chunk  6:  if found then  7:  text = qual_prepend(found,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' text) ⊲ prepend all found qualifiers to words in chunk  8:  lower = max(0,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' index - TRIM)  9:  upper = min(len(text),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' index + TRIM)  10:  new_text = text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='split()[lower:upper]  11:  keep = []  12:  for k in Keeps do  13:  if k in text then keep.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append(k)  14:  new_text = keep + new_text  15:  new_data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='append(new_text)  16: return new_data  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='10  Storing  The final process in the framework is to consolidate the classification results, merging them with  the original data to be stored for later retrieval and analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  The framework facilitates for the storing of all classification outputs to a database of choice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In  this particular application with the data mentioned here, a simple relational SQLite database with  the schema in Figure 16 was used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  id TEXT PRIMARY KEY  vendor TEXT  effective-date DATE  type TEXT  text TEXT  Figure 16: Example Database Schema (for nopoach)  Using this schema, a nopoach database was created where the novel, complete, and classified  dataset could be stored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' An example excerpt of this database’s contents is shown in Figure 17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  Note that some of the meta-data, including the text, was left out for readability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In addition,  we mask the firm name here in order to avoid drawing attention to the specific detail as opposed to  the results of the process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' In essence, the tag column represents the codification of the original text  data into a structured dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' This dataset, in turn, can be used for further research and analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content='  52  id  vendor  effective-date  nopoach  app-7653  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 1  3/24/17  1  app-15957  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 2  9/20/19  1  app-1853  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 3  4/3/15  1  app-7888  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 4  3/28/17  1  app-18366  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 5  6/25/20  1  app-23189  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 6  3/11/22  0  app-22302  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 7  11/1/21  0  468744  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 8  1/17/13  0  app-14481  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 9  4/11/19  1  app-14643  Acme Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
+page_content=' 10  7/22/19  0  Figure 17: Random Sample from the nopoach Database  53' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/i9FAT4oBgHgl3EQfaB2u/content/2301.08549v1.pdf'}
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+Deep Correlation-Aware Kernelized
+Autoencoders for Anomaly Detection in
+Cybersecurity.⋆
+Padmaksha Roy1, Timothy O’Shea1, Laura Freeman2, and Ming Jin1
+1 Department of Electrical and Computer Engineering, Virginia Tech
+2 National Security Institute, Virginia Tech
+{padmaksha,oshea, laura.freeman,jinming}@vt.edu
+Abstract. Unsupervised learning-based anomaly detection in latent space
+has gained importance since discriminating anomalies from normal data
+becomes difficult in high-dimensional space. Both density estimation and
+distance-based methods to detect anomalies in latent space have been
+explored in the past. These methods prove that retaining valuable prop-
+erties of input data in latent space helps in the better reconstruction of
+test data. Moreover, real-world sensor data is skewed and non-Gaussian
+in nature, making mean-based estimators unreliable for skewed data.
+Again, anomaly detection methods based on reconstruction error rely on
+Euclidean distance, which does not consider useful correlation informa-
+tion in the feature space and also fails to accurately reconstruct the data
+when it deviates from the training distribution. In this work, we address
+the limitations of reconstruction error-based autoencoders and propose a
+kernelized autoencoder that leverages a robust form of Mahalanobis dis-
+tance (MD) to measure latent dimension correlation to effectively detect
+both near and far anomalies. This hybrid loss is aided by the principle of
+maximizing the mutual information gain between the latent dimension
+and the high-dimensional prior data space by maximizing the entropy
+of the latent space while preserving useful correlation information of the
+original data in the low-dimensional latent space. The multi-objective
+function has two goals—it measures correlation information in the la-
+tent feature space in the form of robust MD distance and simultaneously
+tries to preserve useful correlation information from the original data
+space in the latent space by maximizing mutual information between
+the prior and latent space.
+Keywords: Anomaly Detection · Robust Mahalanobis Distance · Non-
+parametric Mutual Information Estimation · Kernel Autoencoders · Joint
+Optimization · Cyber-security
+⋆ This project is funded by the Hume Center for National Security and Technology at
+Virginia Tech, Arlington.
+arXiv:2301.00462v1  [cs.LG]  1 Jan 2023
+
+2
+P. Roy et al.
+1
+Introduction
+Autoencoder has an encoding network that provides a mapping from the input
+domain to a latent dimension and the decoder tries to reconstruct the original
+data from the latent dimension [1]. Autoencoders have been successfully used in
+the context of unsupervised learning to effectively learn latent representations in
+low-dimensional space when it is difficult to estimate density in high-dimensional
+[3,23]. Training auto-encoders using a reconstruction error corresponds to max-
+imizing the lower bound of mutual information between input and learned rep-
+resentation [7]. Therefore, regularization methods are of great significance for
+preserving useful information from input space in latent space. In kernel-based
+autoencoders, the pairwise similarities in the data are encoded as a prior ker-
+nel matrix and the auto-encoder tries to reconstruct it from the learned latent
+dimension representations [7]. This helps in learning data representations with
+pre-defined pairwise relationships encoded in the prior kernel matrix [15]. Al-
+though the majority of the reconstruction-based methods assume that the data
+outside the inlier class cannot be effectively compressed and reconstructed, em-
+pirical results suggest that reconstruction-based approaches alone fail to capture
+particular anomalies that lie near the latent dimension manifold of the inlier class
+[6]. The authors [6] highlight the challenging scenario where anomalies with high
+reconstruction error and residing far away from the latent dimension manifold
+can be easily detected but those having low reconstruction error and lying close
+to the manifold with inlier samples are highly unlikely to be detected. We try
+to highlight the importance of treating the far and near anomalies separately
+in the feature space. It is difficult to fix a novelty score as a threshold for such
+cases[6]. This leads us to think of a more comprehensive robust distance metric
+that not only can reliably estimate location and scale but also can take advan-
+tage of the skewed nature of the anomaly data. Most of the current state-of-art
+deep learning models do not consider the case of dealing with both near and
+far anomalies in the feature space with the same model. Also, when the latent
+space is not properly regularized, the latent codes are unable to preserve the
+similarity of the input space and this may lead to an ineffective reconstruction
+of the latent space [13]. Therefore, we perform a latent dimension regularization
+by maximizing mutual information between prior space and latent space, which
+indirectly refers to maximizing the entropy of the latent space. This mutual in-
+formation measure will not only maximize information content or entropy from
+prior space in the latent space but will also quantify the amount of total cor-
+relation of the feature variables in the prior and latent space by disentangling
+the explanatory variables [7]. The importance of the median absolute deviation
+as a robust measure of scale and the median as a robust measure of location in
+presence of outliers have been explored in the past [8,9]. They proved to be ac-
+curate estimators when the data follow a skewed distribution and non-Gaussian
+in nature [12] which most of the real-world datasets are. Moreover, joint opti-
+mization not only helps in the accurate detection of far and near anomalies but
+also helps in effectively reconstructing the out-of-distribution test data. In short,
+our contributions can be summarized below:
+
+Deep Kernelized Robust AE
+3
+– We propose a robust form of Mahalanobis distance metric that uses a robust
+correlation matrix with median and median absolute deviation (MAD) as
+estimators of position and scale respectively, which can effectively capture
+useful correlation information in latent dimension feature space when the
+input features follow a skewed distribution.
+– A completely nonparametric approach to maximizing mutual information
+between prior space and latent dimension using Renyi’s quadratic entropy
+and Cauchy-Schwarz divergence is being developed, which aims to preserve
+useful correlation information of the original feature space in latent space.
+– The joint optimization not only helps to detect near and far anomalies ef-
+fectively in terms of accuracy, precision, and recall but also results in better
+generalization of out-of-distribution data (OOD) when the autoencoder is
+used as a generative model.
+2
+Related Work:
+Unsupervised anomaly detection in latent space has been an interesting area of
+research for a long time. Reconstruction-error-based autoencoders rely on the
+fact that anomalies cannot be effectively compressed and reconstructed from la-
+tent subspaces when the latent space is regularized with useful information of
+the normal data. These methods include PCA [1], kernel PCA [1], Robust deep
+AE [23], [11], [10]. Data representation with kernel methods has been investi-
+gated before [22]. Robust autoencoders are proposed [23]that can distinguish
+anomalies from random noise along with discovering important non-linear fea-
+tures for detecting anomalies. The authors of the paper [15] have developed
+kernel-based autoencoders that aim to optimize a joint objective of minimizing
+reconstruction error from latent space and misalignment error between prior and
+latent space codes in the form of normalized Frobenius distance. The idea of a
+correlation-aware latent space and its use in detecting anomalies was introduced
+here [16]. Mahalanobis distance-based outlier detection methods have been ex-
+plored in the past for multivariate outlier detection[6,20,21,4,18]. Again, joint
+learning of dimensionality reduction and density estimation in latent space has
+been explored in the past. The authors [3] proposed joint optimization of the
+parameters of the deep autoencoder and a mixture model, where latent dimen-
+sion characteristics are fed into the estimation network, which then calculates
+the probability of a sample belonging to a mixture component in a parallel fash-
+ion. In the context of information theory, self-organizing information theoretic
+principles have played an important role in designing information-theoretic cost
+functions in unsupervised learning such as clustering [2,17]. Nonparametric es-
+timators for matrix-based Renyi entropy have previously been developed under
+the ITL framework defined over normalized positive definite matrices [19]. In
+our approach, we combine a robust form of MD to measure correlation in latent
+space and a matrix based on Renyi’s quadratic entropy between prior and latent
+space in the form of Cauchy-Schwarz divergence, which aims to maximize useful
+correlation information from original to latent space. The aim is to capture use-
+
+4
+P. Roy et al.
+ful correlation information in the latent feature space of normal data while also
+maximizing the entropy of the latent space.
+3
+Methodology
+Our methodology combines a robust form of the MD to measure useful feature
+correlation in the latent space with an information-theoretic measure of diver-
+gence to calculate mutual information between latent and original space that
+can be estimated directly from the samples in a nonparametric manner.
+3.1
+Robust Hybrid Error with MD in Latent Space
+The robust distance is calculated by measuring the Mahalanobis distance (DM)
+between the encoded data and the median of the encoded data in the feature
+space together with the reconstruction error of the training samples. The multi-
+objective function is given by
+L = α · DM(Z) + β · Le(X, D(E(X))
+(1)
+The purpose of the robust MD is to effectively capture useful correlation informa-
+tion in the latent dimension feature space. The robust form of the Mahalanobis
+distance (DM) is calculated based on how many standard deviations an encoded
+sample zi is from the median encoded data in the latent space. In the encoded
+space, it is estimated as
+ˆDM (Z) =
+�
+(Z − median)T R−1 (Z − median),
+where ˆR is the estimated feature-based correlation matrix of encoded data in
+the latent space and the robust correlation co-efficient(ρ) is given by:
+ρZi,Zj = E[(Zi − mediani)(Zj − medianj)]
+MADzi, MADzj
+,
+where the MAD is given by
+MADzi = median|Zi − median(Zi)|
+Therefore, we aim to develop a robust method for estimating the feature corre-
+lation in the latent space when the data is highly skewed and deviates from a
+normal distribution. This distance metric leverages the robust association and
+correlation estimator in the latent dimension feature space with the median and
+MAD as robust location and scale estimators. A mean-based correlation coef-
+ficient is strongly biased when the data is highly skewed and non-Gaussian in
+nature.
+
+Deep Kernelized Robust AE
+5
+3.2
+Renyi Entropy, Joint Entropy to Calculate Mutual Information
+Between Prior and Latent Space
+The second part of our objective function focuses on estimating the entropy
+directly from samples in a nonparametric way using kernel techniques. Instead
+of making assumptions about a parametric PDF model in advance, we estimate
+the PDF and compute the quadratic Renyi’s entropy directly from the samples
+in the prior and latent space.
+Renyi’s α order entropy can be considered as a generalization of Shannon
+entropy. Renyi’s quadratic entropy of the prior or original data is estimated as
+ˆH2(X) = − log
+�
+� 1
+N 2
+N
+�
+i=1
+N
+�
+j=1
+Gσ√
+2(xi − xj)
+�
+� .
+(2)
+Similarly, Renyi’s quadratic entropy of the encoded latent dimensional space is
+estimated to be:
+ˆH2(Z) = − log
+�
+� 1
+N 2
+N
+�
+i=1
+N
+�
+j=1
+Gσ√
+2(zi − zj)
+�
+� .
+(3)
+Now, the cross-entropy or the joint entropy can be estimated directly from the
+samples as
+ˆ
+H2(X, Z) = − log
+1
+NXNZ
+Nx
+�
+i=1
+NZ
+�
+j=1
+G√
+2σ (xi − zj) ,
+(4)
+where Gσ(x, z) =
+1
+√
+2πσ2 exp
+�
+(||x−z||2
+2σ2
+�
+is the Gaussian kernel and σ is the kernel
+bandwidth. The argument in equation (4) is called the information potential in
+the literature of self-organizing principle [2]. From the perspective of information
+theory, the dependence measure or the total correlation quantifies how much a
+feature variable m = {m1, m2, m3} ∈ Rd, either latent space or original space,
+deviates from the statistical independence in each dimension d and is expressed
+as
+d
+�
+i=1
+H(mi) − H(m1, m2, m3, ...md),
+(5)
+where H(m) may be the entropy of the input space or the latent space or the joint
+entropy between the latent space and the input space expressed as a difference
+of the joint entropy and the individual entropy of the independent features.
+3.3
+Matrix-based Renyi’s Entropy and Joint Entropy
+Parametric models rely on estimating the underlying distribution based on an
+assumption of the data that is difficult to infer in high dimensional space. There-
+fore, we rely on kernel density estimations to calculate the entropy in a nonpara-
+metric way.
+
+6
+P. Roy et al.
+Let G be the gram matrix obtained from evaluating a positive definite kernel
+on all pairs of samples in the original input space. Thus, (2) can be updated with
+the matrix-based analogue of Renyi’s α entropy [5] of order 2 for a normalized
+positive semi-definite matrix X of size N × N, defined as
+ˆ
+H2(X) = − log2(tr(X2)) = − log2
+� N
+�
+i=1
+λi(X)2
+�
+,
+(6)
+where Xi,j = 1
+N
+Gi,j
+√
+GiiGjj and λi(X) denotes the ith eigenvalue of X. We used this
+measure to estimate the entropy of the original data space.
+Similarly, the matrix-based Renyi’s entropy for the latent space can be given
+as
+ˆ
+H2(Z) = − log2(tr(Z2)) = − log2
+� N
+�
+i=1
+λi(Z)2
+�
+,
+(7)
+Now (4) can be rewritten as the matrix-based analogue of α order joint entropy
+between latent space Z and prior space X, defined as
+ˆ
+H2 (X, Z) = H2
+�
+X ◦ Z
+tr (X ◦ Z)
+�
+,
+(8)
+where ◦ represents the Hadamard product of matrices.
+Based on the above definitions, we calculate the mutual information between
+latent and prior space with the help of the matrix-based normalized Renyi’s
+entropy of the latent space encoded data and the joint entropy between the
+prior space and latent space data.
+3.4
+The Cauchy-Schwarz Divergence
+The measure of closeness between two pdfs p1(x) and p2(x) is provided by
+information-theoretic measures such as the Kullback-Leibler divergence. In this
+paper, we focus on the Cauchy-Schwarz divergence, which is differentiable and
+when used with the robust MD loss aims to achieve a common objective in the
+latent space. If two pdfs p1(x) and p2(x) are non-negative and integrate to one,
+then the Cauchy-Schwarz divergence can be defined as
+Dcs(p1, p2) = − log
+�
+p1(x)p2(z) dx dz
+��
+p2
+1(x) dx
+�
+p22(z) dz
+.
+(9)
+Using the convolution property of Gaussian functions, the nonparametric sample-
+based estimator using the CS pdf divergence is given by
+ˆDcs(p1, p2) = − log
+�N1,N2
+i,j=1 G√
+2σ (xi − zj)
+���N
+i=1 Gσ (x − xi)
+�2 ��N
+i=1 Gσ (z − zj)
+�2 .
+(10)
+
+Deep Kernelized Robust AE
+7
+Fig. 1: The Deep Robust MD Information Theory Autoencoder(DRMDIT-AE).
+The mutual information between input and latent space when expressed in terms
+of Cauchy-Schwarz divergence is as follows
+ˆDCS(px||pz) = log2
+H2(X)H2(Z)
+H2
+2(X, Z) ,
+where H2(X, Z) is the second-order joint entropy between latent and prior space.
+The Cauchy-Schwarz divergence obeys the Cauchy-Schwarz inequality, which
+guarantees that the divergence is equal to zero when the pdfs are equal. By maxi-
+mizing the divergence over the prior or original data space px, i.e., maxpx DCS (px||pz)
+is a trade-off between maximizing the entropy of the latent space while also pre-
+serving useful correlation information from the original space in the latent space.
+3.5
+Objective Function
+The robust information theoretic autoencoder enabled with the robust MD met-
+ric is trained by optimizing the following loss function
+L = α · DM(Z) + β · Le(X, D(E(X)) + max (MIDCS(Z||X))
+(11)
+where DM is the robust MD loss, the second term is the reconstruction loss, and
+α, and β are regularization parameters that range from [0, 1]. The regularization
+parameter attempts to weigh the importance of both objectives. We put 95%
+
+MI(ZIX) + MD(E(X))
+MI(ZIX)
+MD(E(X))
+[k(x1,x))
+k(x1, Xn)
+K(Z)
+K(Z)
+K(P)
+k(Xn,X1)
+.
+k(xn,Xn)
+PriorKernel
+Renyi's Mutual
+Correlation
+Matrix
+Information
+(Robust MD)
+Z
+X'
+Tnl
+Tnd
+NormalData
+Latent
+(Training)
+Space
+E(X)
+D(E(X))8
+P. Roy et al.
+weight on robust MD loss and 5% weight on reconstruction loss. The second part
+of the objective function calculates the mutual information loss between the prior
+and the latent space expressed as a difference of matrix-based Renyi’s quadratic
+entropy of latent and prior space. We estimate the mutual information expressed
+in terms of the Cauchy-Schwarz divergence as a measure of dissimilarity between
+input and the latent space.
+4
+Training and Experimental Results
+For our experiments, we develop a deep autoencoder model with a different num-
+ber of hidden layers and constrain our encoder (E) and decoder (D) network to
+have the same architecture, that is, WE = W T
+D. During training, we use nor-
+mal data as input to our encoder model so that the model learns all the useful
+correlations among the latent dimension features, while also preserving corre-
+lation information from the input space. We keep the batch size high (200-500
+samples) for accurate estimation of the robust MD and the mutual entropy. The
+two hyperparameters of the model that need to be tuned accordingly are the
+kernel bandwidth and the regularization parameter λ. Usually, during training,
+the regularization parameter α can be set to the reciprocal of the mean absolute
+deviation of the Mahalanobis distance of the encoded validation data from the
+encoded train data. Likewise, β can be set to the reciprocal of the mean abso-
+lute deviation of the reconstruction error on the validation data. However, in
+order to take maximum advantage of the robust MD estimator, we find that 5%
+weightage(α) assigned to reconstruction loss and 95% weightage (β) to robust
+MD loss yield the best results.
+4.1
+Choosing an Appropriate Kernel Matrix as Prior to Input Data
+We selected an RBF kernel with a multivariate Gaussian density function to
+perform kernel density estimation to estimate the probability density of the
+data. The kernel bandwidth and the regularization parameter were selected by
+a grid search algorithm. A Gaussian kernel in the range of σ = 0.05 to 0.2 is
+found to be suitable for our training and test data in most cases. The model is
+fine-tuned using a gradient descent algorithm based on the ADAM optimizer.
+Since it is important to choose the normal data distribution carefully for our
+model, we remove those samples with skewed features in the normal data. They
+might have occurred due to some abnormal events, but these samples still cannot
+be considered real-time attacks and therefore need to be discarded.
+4.2
+Datasets
+We selected two benchmark datasets: CSE-CIC-IDS2018 and NSL-KDD for our
+experiments.
+
+Deep Kernelized Robust AE
+9
+Datasets
+Total Feats Model Feats Samples(train) Anomaly Ratio (test)
+CSE-CIC-IDS
+79
+29
+10000
+0.5
+NSL-KDD
+43
+20
+10000
+0.5
+Table 1: Details of the datasets.
+– CSE-CIC-IDS2018: This is a publicly available cybersecurity dataset that
+is made available by Communications Security Establishment (CSE) and the
+Canadian Cybersecurity Institute (CIC). We selected 29 continuous features
+to build the binary classification model.
+– NSL-KDD: This is also a publicly available benchmark cybersecurity dataset
+made available by CIC. It has a total of 43 different features of internet traf-
+fic flow. We selected 20 most influential features after a correlation analysis
+of the features.
+4.3
+Baseline Methods
+– DKAE: The Deep Kernelized Autoencoder [15] has a kernel alignment loss
+that is calculated as the normalized Frobenius distance between the latent
+dimension code matrix and the prior kernel matrix and a reconstruction loss.
+– DAGMM: The Deep Autoencoding Gaussian Mixture Model [3] is an un-
+supervised anomaly detection model that optimizes the parameters of the
+deep autoencoder and the mixture model simultaneously using an estimation
+network to facilitate the learning of a Gaussian Mixture Model (GMM).
+– VAE: VAE leverages a probabilistic encoder-decoder network and the recon-
+struction probability is used for detecting anomalies. Although it performs
+latent dimension regularization, it assumes a parametric distribution of the
+data which is mostly Gaussian.
+– MD-based Autoencoder: This model [6] also leverages MD in the latent
+space with mean as the estimator of location and the covariance in the feature
+space.
+4.4
+Metrics and Observation
+We considered the standard metrics such as accuracy, precision, and recall to
+demonstrate our anomaly detection performance. For our experiments, we con-
+sidered two sets of training and test data. A total of 10k normal data samples
+are used as training data and 2k samples consisting of both normal and anomaly
+data are used as test data. During testing, we considered 1000 samples contain-
+ing both normal and abnormal data to test the performance of our model. We
+observe that the proposed model performs equally well on near and far anomalies
+where baseline performance deteriorates in near anomalies. Experimental results
+show that although distant anomalies can be detected with good accuracy by
+
+10
+P. Roy et al.
+(a)
+(b)
+(c)
+(d)
+Fig. 2: The latent dimension visualization shows that the normal and anomaly
+samples are well separated with the learned robust MD autoencoder(on a differ-
+ent scale) Fig (b) and Fig (d) compared to the Euclidean distance Fig (a) and Fig
+(c) for both near and far anomalies. For e.g, if the calculated Euclidean distance
+of a normal sample is 1.0 and an anomaly is 0.5, the new robust MD distance
+of normal sample is 0.1 and anomaly is 0.005, thus making the relative distance
+between a normal and anomaly sample 20 times with the MD distance(especially
+for the near anomalies). Therefore, it can detect the near anomalies which lie
+close to the latent dimension manifold distinctively in the latent space.
+
+Anomaly
+Normal
+1.25
+1.00
+0.75
+0.50
+0.25
+0.00
+0.25
+0.50
+1.5
+1.0
+0.5
+0.5
+0.0
+0.0
+0.5
+1.0
+0.5
+1.5
+1.0
+2.0Anomaly
+Normal
+1e-6
+8
+6
+4
+2
+0
+2
+4
+6
+6
+4
+1e
+0.000557
+0.000558
+0.000559
+0
+0.000560
+0.000561
+-2Malignant
+Benign
+1.5
+1.0
+0.5
+0.0
+0.5
+1.5
+1.0
+0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6
+0.5
+0.0
+0.5Anomaly
+Normal
+9-
+1.5
+le-
+1.0
+0.5
+0.0
+0.5
+1.0
+1.5
+1.0
+1e
+0.5
+0.0
+0.5
+0.0004756
+1.0Deep Kernelized Robust AE
+11
+(a)
+(b)
+(c)
+(d)
+(e)
+(f)
+(g)
+(h)
+(i)
+(j)
+(k)
+(l)
+(m)
+(n)
+(o)
+(p)
+Fig. 3: Comparison of the various models on the basis of detecting far and near
+anomalies in CSE-CIS-IDS data. The X-axis is the number of samples, Y-axis
+is the robust distance. The threshold is chosen based on the best value preci-
+sion, recall, and accuracy of the test data. (a) Detecting Far anomalies with
+DKAE; (b) Detecting Far anomalies with DKAE; (c) Detecting Near anoma-
+lies with DKAE; (d) Detecting Near anomalies with DKAE; (e) Detecting Far
+anomalies with DRMDIT-AE; (f) Detecting Far anomalies with DRMDIT-AE;
+(g) Detecting Near anomalies with DRMDIT-AE ;(h) Detecting Near anomalies
+with DRMDIT-AE; Fig (i) to (p) shows the detection of near and far anomalies
+by the DRMDIT-AE and DKAE models on the NSL-KDD dataset.
+
+1.75
+1.50
+1.25
+distance
+1.00
+0.75
+0.50
+0.25
++ +++ ++. + +★ +++++ ++
+0.00
+0
+100
+200
+300
+400
+500
+Number of samples0.7
+0.6
+distance
+0.5
+0.4
+0.3
+a
+0.2
+0.1
+0
+100
+200
+300
+00F
+500
+Number of samples0.07
+0.06
+e
+0.05
+istance
+0.04
+0.03
+0.02
+TO'0
+0.00
+0
+100
+200
+300
+400
+500
+Number of samples0.10
+0.08
+istance
+0.06
+0.04
+0.02
+00'0
+0
+100
+200
+300
+400
+5008
+distance
+6
+2
+100
+200
+300
+400
+500
+Numberofsamples4
+distance
+100
+200
+300
+400
+500
+Number of samples2.25
+2.00
+1.75
+istance
+1.50
+1.25
+1.00
+0.75
+0.50
+0.25
+0
+100
+200
+300
+400
+500
+Number of samples2.5
+distance
+2.0
+1.5
+1.0
+0.5
+0
+100
+200
+300
+400
+500
+Number of samples0.10
+0.09
+0.08
+distance
+0.07
+0.06
+0.05
+0.04
+0.03
+0.02
+100
+200
+300
+400
+5000.35
+0.30
+distance
+0.25
+0.20
+0.15
+0.10
+0.05
+100
+200
+300
+400
+500
+Number of samples0.05
+distance
+e
+0.04
+0.03
+0.02
+0.01
+0
+100
+200
+300
+400
+500
+Numberofsamples0.10
+0.09
+0.08
+distance
+0.07
+0.06
+0.05
+0.04
+0.03
+0.02
+0
+100
+200
+300
+400
+500
+Number of samples30
+25
+distance
+20
+15
+10
+5
+0
+100
+200
+300
+400
+500
+Number of samples10
+distance
+6
+100
+200
+300
+00F
+500
+Number of samples1.0
+0.8
+distance
+0.6
+0.4
+0.2
+0.0
+0
+100
+200
+300
+400
+500
+Number of samples1.0
+0.8
+distance
+0.6
+0.4
+0.2
+0
+100
+200
+300
+400
+500
+Number of samples12
+P. Roy et al.
+CSE-CIC-IDS Dataset
+NSL-KDD
+Model
+Type Accuracy Precision Recall AUC Accuracy Precision Recall AUC
+DRMDIT-AE Near
+71.5
+70.7
+73.4 74.5
+92.4
+94.6
+93.1 96.0
+Far
+78.9
+80.1
+82.4 78.9
+91.2
+95.2
+95.4 97.3
+DKAE
+Near
+50
+75.2
+50.8
+71.4
+82.0
+81.6
+92.2
+95.6
+Far
+79.8
+85.2
+79.8
+74.5
+74.5
+74.7
+74.7
+74.5
+DAGMM
+Near
+67.6
+68.1
+67.9
+67.9
+95.4
+86.9
+89.3
+88.8
+Far
+66.6
+67.1
+66.8
+65.1
+94
+86.8
+89.1
+91.9
+VAE
+Near
+61.9
+62.1
+66.6
+65.7
+84.2
+84.9
+88.0
+86.4
+Far
+75.9
+74.5
+72.2
+73.3
+87.0
+85.3
+81.0
+83.6
+MD-AE
+Near
+57.3
+57.2
+52.2
+53.4
+82.3
+83.9
+82.5
+82.6
+Far
+72.8
+70.6
+71.6
+71.6
+81.3
+83.6
+83.5
+79.5
+CSE-CIC-IDS Dataset
+NSL-KDD
+Model
+Type Accuracy Precision Recall AUC Accuracy Precision Recall AUC
+DRMDIT-AE Near
+71.5
+74.6
+71.4 93.8
+96.3
+94.6
+93.1 96.0
+Far
+74.3
+79.2
+70.3
+93.1
+98.2
+87.8
+95.4 97.3
+DKAE
+Near
+50.3
+50.2
+55.8
+81.6
+81.6
+81.6
+92.2
+95.6
+Far
+79.8
+79.0
+79.8
+73.5
+74.1
+73.5
+95.0
+97.1
+DAGMM
+Near
+55.1
+57.8
+53.7
+57.8
+95.4
+86.5
+89.3
+91.9
+Far
+65.1
+66.0
+65.6
+65.6
+94.8
+95.8
+95.3
+95.3
+VAE
+Near
+65.7
+62.1
+59.5
+62.1
+87.4
+80.2
+81.5
+83.9
+Far
+74.3
+75.6
+70.6
+75.6
+89.8
+83.2
+81.3
+82.6
+MD-AE
+Near
+62.6
+60.9
+61.7
+65.3
+83.5
+85.1
+84.3
+79.2
+Far
+73.3
+78.7
+56.7
+68.4
+80.2
+83.6
+81.5
+82.0
+Table 2: Performance of the proposed method and baseline methods .
+a number of models, the DRMDIT-AE shows significantly good performance in
+identifying near-abnormalities in the feature space. Empirical results show that
+the robust distance lies in the range of 0.01-0.08 for the normal data(normalized
+CIC-IDS data) and a value greater than 0.08 for the far anomalies and a value
+less than 0.01 for the near anomalies while reconstructing from the latent space
+which is regularized for the normal data. In order to show the effectiveness of
+the robust correlation matrix and the robust position and scale estimator in re-
+constructing OOD test data, we compute the MSE on the test data and show
+its efficiency in reconstructing out-of-distribution data. The proposed autoen-
+coder shows an improvement of 10%-15% in MSE while reconstructing out-
+of-distribution data compared to the DKAE model which uses reconstruction
+error and kernel misalignment error. The code for our model implementation is
+available on GitHub.3
+5
+Conclusion
+In this paper, we propose a correlation-aware deep kernelized autoencoder that
+leverages the robust MD in latent feature space and the principle of Renyi’s mu-
+3 https://github.com/padmaksha18/DRMDIT-AE
+
+Deep Kernelized Robust AE
+13
+tual information maximization between prior and latent space in order to detect
+anomalies in cyber-security data. The MAD- and median-based MDs and their
+robust correlation estimators are useful indicators of specific kinds of anomalies
+especially when the data is non-Gaussian. We report the model’s performance
+in detecting both near and far anomalies with standard classification metrics
+across 2 real-world cybersecurity datasets. This approach can also help recon-
+struct out-of-distribution data more accurately because of the robustness of the
+MAD and median estimators, which reconstruction error-based models fail to do
+in the case of OOD data. In the future, we would like to explore further in this
+direction and try to address the important problem of domain generalization in
+the field of cybersecurity, where a model trained on a number of known kinds of
+attacks can generalize to unseen attacks, also known as zero-day attacks.
+References
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+tives. In: Springer Science & Business Media(2010).
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+Cristian and Cho, Daeki and Chen, Haifeng:Deep autoencoding gaussian mixture
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+simple fix to mahalanobis distance for improving near-ood detection. arXiv preprint
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+and Phan, Buu and Vernekar, Sachin, Jose In: Improving reconstruction autoencoder
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+8. Huber, Peter J: International encyclopedia of statistical science. Springer, pp. 1248–
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+9. Hampel, Frank R: Robust statistics: A brief introduction and overview. Seminar f¨ur
+Statistik, Eidgen¨ossische Technische Hochschule,vol 04 (2001)
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+Springer,vol. 45,pp. 791–806 (2017)
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+Advances in neural information processing systems, vol. 31 , (2018)
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+tion with robust deep autoencoders. Proceedings of the 23rd ACM SIGKDD inter-
+national conference on knowledge discovery and data mining, pp. 665–674 ,(2017)
+15. Kampffmeyer, Michael and Løkse, Sigurd and Bianchi, Filippo M and Jenssen,
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+ference on image analysis, pp. 419–430 ,Springer(2017)
+16. Fan, H., Zhang, F., Wang, R., Xi, L., Li, Z. (2020, May). Correlation-aware deep
+generative model for unsupervised anomaly detection. In Pacific-Asia Conference
+on Knowledge Discovery and Data Mining (pp. 688-700). Springer, Cham.
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+18. Fort, S., Ren, J., Lakshminarayanan, B. (2021). Exploring the limits of out-of-
+distribution detection. Advances in Neural Information Processing Systems, 34,
+7068-7081.
+19. Giraldo, L. G. S., Rao, M., Principe, J. C. (2014). Measures of entropy from data
+using infinitely divisible kernels. IEEE Transactions on Information Theory, 61(1),
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+20. Ghorbani, H. (2019). Mahalanobis distance and its application for detecting mul-
+tivariate outliers. Facta Univ Ser Math Inform, 34(3), 583-95.
+21. Todeschini, R., Ballabio, D., Consonni, V., Sahigara, F., Filzmoser, P. (2013).
+Locally centred Mahalanobis distance: a new distance measure with salient features
+towards outlier detection. Analytica chimica acta, 787, 1-9.
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+on knowledge discovery and data mining (pp. 665-674).
+
diff --git a/p9AyT4oBgHgl3EQfl_hG/content/tmp_files/load_file.txt b/p9AyT4oBgHgl3EQfl_hG/content/tmp_files/load_file.txt
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf,len=610
+page_content='Deep Correlation-Aware Kernelized  Autoencoders for Anomaly Detection in  Cybersecurity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='⋆  Padmaksha Roy1, Timothy O’Shea1, Laura Freeman2, and Ming Jin1  1 Department of Electrical and Computer Engineering, Virginia Tech  2 National Security Institute, Virginia Tech  {padmaksha,oshea, laura.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='freeman,jinming}@vt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='edu  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Unsupervised learning-based anomaly detection in latent space  has gained importance since discriminating anomalies from normal data  becomes difficult in high-dimensional space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Both density estimation and  distance-based methods to detect anomalies in latent space have been  explored in the past.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' These methods prove that retaining valuable prop-  erties of input data in latent space helps in the better reconstruction of  test data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Moreover, real-world sensor data is skewed and non-Gaussian  in nature, making mean-based estimators unreliable for skewed data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Again, anomaly detection methods based on reconstruction error rely on  Euclidean distance, which does not consider useful correlation informa-  tion in the feature space and also fails to accurately reconstruct the data  when it deviates from the training distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In this work, we address  the limitations of reconstruction error-based autoencoders and propose a  kernelized autoencoder that leverages a robust form of Mahalanobis dis-  tance (MD) to measure latent dimension correlation to effectively detect  both near and far anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' This hybrid loss is aided by the principle of  maximizing the mutual information gain between the latent dimension  and the high-dimensional prior data space by maximizing the entropy  of the latent space while preserving useful correlation information of the  original data in the low-dimensional latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The multi-objective  function has two goals—it measures correlation information in the la-  tent feature space in the form of robust MD distance and simultaneously  tries to preserve useful correlation information from the original data  space in the latent space by maximizing mutual information between  the prior and latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Keywords: Anomaly Detection · Robust Mahalanobis Distance · Non-  parametric Mutual Information Estimation · Kernel Autoencoders · Joint  Optimization · Cyber-security  ⋆ This project is funded by the Hume Center for National Security and Technology at  Virginia Tech, Arlington.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='00462v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='LG]  1 Jan 2023  2  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Roy et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  1  Introduction  Autoencoder has an encoding network that provides a mapping from the input  domain to a latent dimension and the decoder tries to reconstruct the original  data from the latent dimension [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Autoencoders have been successfully used in  the context of unsupervised learning to effectively learn latent representations in  low-dimensional space when it is difficult to estimate density in high-dimensional  [3,23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Training auto-encoders using a reconstruction error corresponds to max-  imizing the lower bound of mutual information between input and learned rep-  resentation [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Therefore, regularization methods are of great significance for  preserving useful information from input space in latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In kernel-based  autoencoders, the pairwise similarities in the data are encoded as a prior ker-  nel matrix and the auto-encoder tries to reconstruct it from the learned latent  dimension representations [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' This helps in learning data representations with  pre-defined pairwise relationships encoded in the prior kernel matrix [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Al-  though the majority of the reconstruction-based methods assume that the data  outside the inlier class cannot be effectively compressed and reconstructed, em-  pirical results suggest that reconstruction-based approaches alone fail to capture  particular anomalies that lie near the latent dimension manifold of the inlier class  [6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The authors [6] highlight the challenging scenario where anomalies with high  reconstruction error and residing far away from the latent dimension manifold  can be easily detected but those having low reconstruction error and lying close  to the manifold with inlier samples are highly unlikely to be detected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We try  to highlight the importance of treating the far and near anomalies separately  in the feature space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' It is difficult to fix a novelty score as a threshold for such  cases[6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' This leads us to think of a more comprehensive robust distance metric  that not only can reliably estimate location and scale but also can take advan-  tage of the skewed nature of the anomaly data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Most of the current state-of-art  deep learning models do not consider the case of dealing with both near and  far anomalies in the feature space with the same model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Also, when the latent  space is not properly regularized, the latent codes are unable to preserve the  similarity of the input space and this may lead to an ineffective reconstruction  of the latent space [13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Therefore, we perform a latent dimension regularization  by maximizing mutual information between prior space and latent space, which  indirectly refers to maximizing the entropy of the latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' This mutual in-  formation measure will not only maximize information content or entropy from  prior space in the latent space but will also quantify the amount of total cor-  relation of the feature variables in the prior and latent space by disentangling  the explanatory variables [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The importance of the median absolute deviation  as a robust measure of scale and the median as a robust measure of location in  presence of outliers have been explored in the past [8,9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' They proved to be ac-  curate estimators when the data follow a skewed distribution and non-Gaussian  in nature [12] which most of the real-world datasets are.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Moreover, joint opti-  mization not only helps in the accurate detection of far and near anomalies but  also helps in effectively reconstructing the out-of-distribution test data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In short,  our contributions can be summarized below:  Deep Kernelized Robust AE  3  – We propose a robust form of Mahalanobis distance metric that uses a robust  correlation matrix with median and median absolute deviation (MAD) as  estimators of position and scale respectively, which can effectively capture  useful correlation information in latent dimension feature space when the  input features follow a skewed distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – A completely nonparametric approach to maximizing mutual information  between prior space and latent dimension using Renyi’s quadratic entropy  and Cauchy-Schwarz divergence is being developed, which aims to preserve  useful correlation information of the original feature space in latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – The joint optimization not only helps to detect near and far anomalies ef-  fectively in terms of accuracy, precision, and recall but also results in better  generalization of out-of-distribution data (OOD) when the autoencoder is  used as a generative model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  2  Related Work:  Unsupervised anomaly detection in latent space has been an interesting area of  research for a long time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Reconstruction-error-based autoencoders rely on the  fact that anomalies cannot be effectively compressed and reconstructed from la-  tent subspaces when the latent space is regularized with useful information of  the normal data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' These methods include PCA [1], kernel PCA [1], Robust deep  AE [23], [11], [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Data representation with kernel methods has been investi-  gated before [22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Robust autoencoders are proposed [23]that can distinguish  anomalies from random noise along with discovering important non-linear fea-  tures for detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The authors of the paper [15] have developed  kernel-based autoencoders that aim to optimize a joint objective of minimizing  reconstruction error from latent space and misalignment error between prior and  latent space codes in the form of normalized Frobenius distance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The idea of a  correlation-aware latent space and its use in detecting anomalies was introduced  here [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Mahalanobis distance-based outlier detection methods have been ex-  plored in the past for multivariate outlier detection[6,20,21,4,18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Again, joint  learning of dimensionality reduction and density estimation in latent space has  been explored in the past.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The authors [3] proposed joint optimization of the  parameters of the deep autoencoder and a mixture model, where latent dimen-  sion characteristics are fed into the estimation network, which then calculates  the probability of a sample belonging to a mixture component in a parallel fash-  ion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In the context of information theory, self-organizing information theoretic  principles have played an important role in designing information-theoretic cost  functions in unsupervised learning such as clustering [2,17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Nonparametric es-  timators for matrix-based Renyi entropy have previously been developed under  the ITL framework defined over normalized positive definite matrices [19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In  our approach, we combine a robust form of MD to measure correlation in latent  space and a matrix based on Renyi’s quadratic entropy between prior and latent  space in the form of Cauchy-Schwarz divergence, which aims to maximize useful  correlation information from original to latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The aim is to capture use-  4  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Roy et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  ful correlation information in the latent feature space of normal data while also  maximizing the entropy of the latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  3  Methodology  Our methodology combines a robust form of the MD to measure useful feature  correlation in the latent space with an information-theoretic measure of diver-  gence to calculate mutual information between latent and original space that  can be estimated directly from the samples in a nonparametric manner.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='1  Robust Hybrid Error with MD in Latent Space  The robust distance is calculated by measuring the Mahalanobis distance (DM)  between the encoded data and the median of the encoded data in the feature  space together with the reconstruction error of the training samples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The multi-  objective function is given by  L = α · DM(Z) + β · Le(X, D(E(X))  (1)  The purpose of the robust MD is to effectively capture useful correlation informa-  tion in the latent dimension feature space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The robust form of the Mahalanobis  distance (DM) is calculated based on how many standard deviations an encoded  sample zi is from the median encoded data in the latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In the encoded  space,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' it is estimated as  ˆDM (Z) =  �  (Z − median)T R−1 (Z − median),' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  where ˆR is the estimated feature-based correlation matrix of encoded data in  the latent space and the robust correlation co-efficient(ρ) is given by:  ρZi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='Zj = E[(Zi − mediani)(Zj − medianj)]  MADzi,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' MADzj  ,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  where the MAD is given by  MADzi = median|Zi − median(Zi)|  Therefore,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' we aim to develop a robust method for estimating the feature corre-  lation in the latent space when the data is highly skewed and deviates from a  normal distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' This distance metric leverages the robust association and  correlation estimator in the latent dimension feature space with the median and  MAD as robust location and scale estimators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' A mean-based correlation coef-  ficient is strongly biased when the data is highly skewed and non-Gaussian in  nature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Deep Kernelized Robust AE  5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='2  Renyi Entropy, Joint Entropy to Calculate Mutual Information  Between Prior and Latent Space  The second part of our objective function focuses on estimating the entropy  directly from samples in a nonparametric way using kernel techniques.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Instead  of making assumptions about a parametric PDF model in advance, we estimate  the PDF and compute the quadratic Renyi’s entropy directly from the samples  in the prior and latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Renyi’s α order entropy can be considered as a generalization of Shannon  entropy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Renyi’s quadratic entropy of the prior or original data is estimated as  ˆH2(X) = − log  �  � 1  N 2  N  �  i=1  N  �  j=1  Gσ√  2(xi − xj)  �  � .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  (2)  Similarly, Renyi’s quadratic entropy of the encoded latent dimensional space is  estimated to be:  ˆH2(Z) = − log  �  � 1  N 2  N  �  i=1  N  �  j=1  Gσ√  2(zi − zj)  �  � .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  (3)  Now, the cross-entropy or the joint entropy can be estimated directly from the  samples as  ˆ  H2(X, Z) = − log  1  NXNZ  Nx  �  i=1  NZ  �  j=1  G√  2σ (xi − zj) ,  (4)  where Gσ(x, z) =  1  √  2πσ2 exp  �  (||x−z||2  2σ2  �  is the Gaussian kernel and σ is the kernel  bandwidth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The argument in equation (4) is called the information potential in  the literature of self-organizing principle [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' From the perspective of information  theory, the dependence measure or the total correlation quantifies how much a  feature variable m = {m1, m2, m3} ∈ Rd, either latent space or original space,  deviates from the statistical independence in each dimension d and is expressed  as  d  �  i=1  H(mi) − H(m1, m2, m3, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='md),  (5)  where H(m) may be the entropy of the input space or the latent space or the joint  entropy between the latent space and the input space expressed as a difference  of the joint entropy and the individual entropy of the independent features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='3  Matrix-based Renyi’s Entropy and Joint Entropy  Parametric models rely on estimating the underlying distribution based on an  assumption of the data that is difficult to infer in high dimensional space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' There-  fore, we rely on kernel density estimations to calculate the entropy in a nonpara-  metric way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  6  P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Roy et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Let G be the gram matrix obtained from evaluating a positive definite kernel  on all pairs of samples in the original input space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Thus, (2) can be updated with  the matrix-based analogue of Renyi’s α entropy [5] of order 2 for a normalized  positive semi-definite matrix X of size N × N, defined as  ˆ  H2(X) = − log2(tr(X2)) = − log2  � N  �  i=1  λi(X)2  �  ,  (6)  where Xi,j = 1  N  Gi,j  √  GiiGjj and λi(X) denotes the ith eigenvalue of X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We used this  measure to estimate the entropy of the original data space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Similarly, the matrix-based Renyi’s entropy for the latent space can be given  as  ˆ  H2(Z) = − log2(tr(Z2)) = − log2  � N  �  i=1  λi(Z)2  �  ,  (7)  Now (4) can be rewritten as the matrix-based analogue of α order joint entropy  between latent space Z and prior space X, defined as  ˆ  H2 (X, Z) = H2  �  X ◦ Z  tr (X ◦ Z)  �  ,  (8)  where ◦ represents the Hadamard product of matrices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Based on the above definitions, we calculate the mutual information between  latent and prior space with the help of the matrix-based normalized Renyi’s  entropy of the latent space encoded data and the joint entropy between the  prior space and latent space data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='4  The Cauchy-Schwarz Divergence  The measure of closeness between two pdfs p1(x) and p2(x) is provided by  information-theoretic measures such as the Kullback-Leibler divergence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In this  paper, we focus on the Cauchy-Schwarz divergence, which is differentiable and  when used with the robust MD loss aims to achieve a common objective in the  latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' If two pdfs p1(x) and p2(x) are non-negative and integrate to one,  then the Cauchy-Schwarz divergence can be defined as  Dcs(p1, p2) = − log  �  p1(x)p2(z) dx dz  ��  p2  1(x) dx  �  p22(z) dz  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  (9)  Using the convolution property of Gaussian functions, the nonparametric sample-  based estimator using the CS pdf divergence is given by  ˆDcs(p1, p2) = − log  �N1,N2  i,j=1 G√  2σ (xi − zj)  ���N  i=1 Gσ (x − xi)  �2 ��N  i=1 Gσ (z − zj)  �2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  (10)  Deep Kernelized Robust AE  7  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' 1: The Deep Robust MD Information Theory Autoencoder(DRMDIT-AE).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  The mutual information between input and latent space when expressed in terms  of Cauchy-Schwarz divergence is as follows  ˆDCS(px||pz) = log2  H2(X)H2(Z)  H2  2(X, Z) ,  where H2(X, Z) is the second-order joint entropy between latent and prior space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  The Cauchy-Schwarz divergence obeys the Cauchy-Schwarz inequality, which  guarantees that the divergence is equal to zero when the pdfs are equal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' By maxi-  mizing the divergence over the prior or original data space px, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=', maxpx DCS (px||pz)  is a trade-off between maximizing the entropy of the latent space while also pre-  serving useful correlation information from the original space in the latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='5  Objective Function  The robust information theoretic autoencoder enabled with the robust MD met-  ric is trained by optimizing the following loss function  L = α · DM(Z) + β · Le(X, D(E(X)) + max (MIDCS(Z||X))  (11)  where DM is the robust MD loss, the second term is the reconstruction loss, and  α, and β are regularization parameters that range from [0, 1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The regularization  parameter attempts to weigh the importance of both objectives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We put 95%  MI(ZIX) + MD(E(X))  MI(ZIX)  MD(E(X))  [k(x1,x))  k(x1, Xn)  K(Z)  K(Z)  K(P)  k(Xn,X1)  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content="  k(xn,Xn)  PriorKernel  Renyi's Mutual  Correlation  Matrix  Information  (Robust MD)  Z  X'  Tnl  Tnd  NormalData  Latent  (Training)  Space  E(X)  D(E(X))8  P." metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Roy et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  weight on robust MD loss and 5% weight on reconstruction loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The second part  of the objective function calculates the mutual information loss between the prior  and the latent space expressed as a difference of matrix-based Renyi’s quadratic  entropy of latent and prior space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We estimate the mutual information expressed  in terms of the Cauchy-Schwarz divergence as a measure of dissimilarity between  input and the latent space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  4  Training and Experimental Results  For our experiments, we develop a deep autoencoder model with a different num-  ber of hidden layers and constrain our encoder (E) and decoder (D) network to  have the same architecture, that is, WE = W T  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' During training, we use nor-  mal data as input to our encoder model so that the model learns all the useful  correlations among the latent dimension features, while also preserving corre-  lation information from the input space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We keep the batch size high (200-500  samples) for accurate estimation of the robust MD and the mutual entropy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The  two hyperparameters of the model that need to be tuned accordingly are the  kernel bandwidth and the regularization parameter λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Usually, during training,  the regularization parameter α can be set to the reciprocal of the mean absolute  deviation of the Mahalanobis distance of the encoded validation data from the  encoded train data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Likewise, β can be set to the reciprocal of the mean abso-  lute deviation of the reconstruction error on the validation data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' However, in  order to take maximum advantage of the robust MD estimator, we find that 5%  weightage(α) assigned to reconstruction loss and 95% weightage (β) to robust  MD loss yield the best results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='1  Choosing an Appropriate Kernel Matrix as Prior to Input Data  We selected an RBF kernel with a multivariate Gaussian density function to  perform kernel density estimation to estimate the probability density of the  data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The kernel bandwidth and the regularization parameter were selected by  a grid search algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' A Gaussian kernel in the range of σ = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='05 to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='2 is  found to be suitable for our training and test data in most cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The model is  fine-tuned using a gradient descent algorithm based on the ADAM optimizer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Since it is important to choose the normal data distribution carefully for our  model, we remove those samples with skewed features in the normal data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' They  might have occurred due to some abnormal events, but these samples still cannot  be considered real-time attacks and therefore need to be discarded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='2  Datasets  We selected two benchmark datasets: CSE-CIC-IDS2018 and NSL-KDD for our  experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  Deep Kernelized Robust AE  9  Datasets  Total Feats Model Feats Samples(train) Anomaly Ratio (test)  CSE-CIC-IDS  79  29  10000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='5  NSL-KDD  43  20  10000  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='5  Table 1: Details of the datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – CSE-CIC-IDS2018: This is a publicly available cybersecurity dataset that  is made available by Communications Security Establishment (CSE) and the  Canadian Cybersecurity Institute (CIC).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We selected 29 continuous features  to build the binary classification model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – NSL-KDD: This is also a publicly available benchmark cybersecurity dataset  made available by CIC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' It has a total of 43 different features of internet traf-  fic flow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We selected 20 most influential features after a correlation analysis  of the features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='3  Baseline Methods  – DKAE: The Deep Kernelized Autoencoder [15] has a kernel alignment loss  that is calculated as the normalized Frobenius distance between the latent  dimension code matrix and the prior kernel matrix and a reconstruction loss.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – DAGMM: The Deep Autoencoding Gaussian Mixture Model [3] is an un-  supervised anomaly detection model that optimizes the parameters of the  deep autoencoder and the mixture model simultaneously using an estimation  network to facilitate the learning of a Gaussian Mixture Model (GMM).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – VAE: VAE leverages a probabilistic encoder-decoder network and the recon-  struction probability is used for detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Although it performs  latent dimension regularization, it assumes a parametric distribution of the  data which is mostly Gaussian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  – MD-based Autoencoder: This model [6] also leverages MD in the latent  space with mean as the estimator of location and the covariance in the feature  space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='4  Metrics and Observation  We considered the standard metrics such as accuracy, precision, and recall to  demonstrate our anomaly detection performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' For our experiments, we con-  sidered two sets of training and test data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' A total of 10k normal data samples  are used as training data and 2k samples consisting of both normal and anomaly  data are used as test data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' During testing, we considered 1000 samples contain-  ing both normal and abnormal data to test the performance of our model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We  observe that the proposed model performs equally well on near and far anomalies  where baseline performance deteriorates in near anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+page_content=' 2: The latent dimension visualization shows that the normal and anomaly  samples are well separated with the learned robust MD autoencoder(on a differ-  ent scale) Fig (b) and Fig (d) compared to the Euclidean distance Fig (a) and Fig  (c) for both near and far anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+page_content='0  Table 2: Performance of the proposed method and baseline methods .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  a number of models, the DRMDIT-AE shows significantly good performance in  identifying near-abnormalities in the feature space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Empirical results show that  the robust distance lies in the range of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='01-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='08 for the normal data(normalized  CIC-IDS data) and a value greater than 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='08 for the far anomalies and a value  less than 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='01 for the near anomalies while reconstructing from the latent space  which is regularized for the normal data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In order to show the effectiveness of  the robust correlation matrix and the robust position and scale estimator in re-  constructing OOD test data, we compute the MSE on the test data and show  its efficiency in reconstructing out-of-distribution data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The proposed autoen-  coder shows an improvement of 10%-15% in MSE while reconstructing out-  of-distribution data compared to the DKAE model which uses reconstruction  error and kernel misalignment error.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The code for our model implementation is  available on GitHub.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='3  5  Conclusion  In this paper, we propose a correlation-aware deep kernelized autoencoder that  leverages the robust MD in latent feature space and the principle of Renyi’s mu-  3 https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='com/padmaksha18/DRMDIT-AE  Deep Kernelized Robust AE  13  tual information maximization between prior and latent space in order to detect  anomalies in cyber-security data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' The MAD- and median-based MDs and their  robust correlation estimators are useful indicators of specific kinds of anomalies  especially when the data is non-Gaussian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' We report the model’s performance  in detecting both near and far anomalies with standard classification metrics  across 2 real-world cybersecurity datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' This approach can also help recon-  struct out-of-distribution data more accurately because of the robustness of the  MAD and median estimators, which reconstruction error-based models fail to do  in the case of OOD data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In the future, we would like to explore further in this  direction and try to address the important problem of domain generalization in  the field of cybersecurity, where a model trained on a number of known kinds of  attacks can generalize to unseen attacks, also known as zero-day attacks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  References  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' Chandola, Varun and Banerjee, Arindam and Kumar, Vipin: Anomaly detection: A  survey.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+page_content=' 41,pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+page_content=' In: Springer Science & Business Media(2010).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+page_content=' Zong, Bo and Song, Qi and Min, Martin Renqiang and Cheng, Wei and Lumezanu,  Cristian and Cho, Daeki and Chen, Haifeng:Deep autoencoding gaussian mixture  model for unsupervised anomaly detection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In: International conference on learning  representations(2018).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+page_content=' Anomaly detection with robust deep  autoencoders.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
+page_content=' In Proceedings of the 23rd ACM SIGKDD international conference  on knowledge discovery and data mining (pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/p9AyT4oBgHgl3EQfl_hG/content/2301.00462v1.pdf'}
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+Kerr-type naked singularity: its shadow and accretion
+Aydin Tavlayan1, ∗ and Bayram Tekin1, †
+1Department of Physics,
+Middle East Technical University, 06800 Ankara, Turkey
+We study null and timelike constant radii geodesics in the environment of an over-spinning Kerr-
+type naked singularity. We are particularly interested in two topics: first, the differences of the
+shadows of the naked rotating singularity and the Kerr black hole; and second, the spinning down
+effect of the particles falling from the accretion disk. Our findings are as follows: around the naked
+singularity, the non-equatorial prograde orbits in the in Kerr black hole remain intact up to a
+critical rotation parameter (α = 4
+√
+2
+3
+√
+3) and cease to exist above this value. This has an important
+consequence in the shadow of the naked singularity if the shadow is registered by an observer on
+the rotation plane or close to it as the shadow cannot be distinguished from that of a Kerr black
+hole viewed from the same angle. We also show that the timelike retrograde orbits in the equatorial
+plane immediately (after about an 8% increase in mass) reduce the spin parameter of the naked
+singularity from larger values to α = 1 at which an event horizon appears. This happens because
+the retrograde orbits have a larger capture cross-section than the prograde ones.
+So if a naked
+singularity happens to have an accretion disk, it will not remain naked for long, an event horizon
+forms.
+I.
+INTRODUCTION
+Nature has a very efficient way in constraining some phys-
+ical quantities; it just uses the square-roots, for exam-
+ple the speed of any object is restricted to less than the
+speed of light as the factor
+�
+1 − v2/c2 appears in rel-
+ativistic physics.
+Similarly, in black hole physics, the
+rotation of a black hole is restricted because the factor
+√
+1 − α2, with α being the dimensionless rotation param-
+eter given in SI units in terms of the spin J and mass m
+as α = cJ/(Gm2), appears in the location of the event
+horizon. If α > 1, there is no event horizon and the black
+hole becomes a rotating, massive naked singularity, still
+a solution to vacuum Einstein equations.
+As the stars, or star systems typically have α > 1 be-
+fore a black hole is produced, it is clear that the angular
+momentum of the collapsing matter must be depleted to
+the values α < 1 to form a black hole, otherwise a naked
+singularity is formed. Even though one can envisage ways
+to deplete the angular momentum, we still do not know
+how Nature solves this problem exactly. [For example,
+for our solar system α ≈ 35 and most of the contribution
+comes from Jupiter’s angular momentum which is located
+far away from the central mass, the Sun.] Some observed
+black holes are rotating close to the extreme value α = 1.
+With the singularity theorem of Penrose [1], a singularity
+is guaranteed to occur in a gravitational collapse under
+reasonable assumptions on the energy-momentum tensor
+of matter. However an event horizon is not guaranteed
+to form, we only have an expectation dubbed as "the
+cosmic censorship hypothesis" [2] which states that col-
+lapsing matter do not form a naked singularity but it
+does not state that naked singularities do not exist on
+∗Electronic address: aydint@metu.edu.tr
+†Electronic address: btekin@metu.edu.tr
+their own. Due to this state of affairs, one is necessar-
+ily curious about the observable differences in the causal
+environment of a naked singularity and the Kerr black
+hole.
+For example, can a naked singularity mimic the
+Kerr black hole [3] as far as its shadow [4] is concerned?
+Can accretion of matter to a naked singularity spin down
+its rotation in such a way that an event horizon forms ?
+In this work, we study various null and timelike orbits
+around a naked singularity and make comparisons with
+the Kerr black hole; we also give a detailed account of ac-
+cretion of matter carrying angular momentum and mass
+to a naked singularity assuming a thin equatorial accre-
+tion disk about it.
+The lay-out of this paper is as follows: In Sec. II we
+study the null spherical geodesics around the naked sin-
+gularity. In Sec. III we plot the shadows of various naked
+singularities. In Sec. IV we concentrated on the null or-
+bits at the critical inclination angle. In Sec. V we ex-
+tended discussion to timelike geodesics. In Sec. VI we
+give a detailed study of the accretion for both Kerr black
+hole and the Kerr-type singularity for thin disks and show
+the spinning-down effect for the naked singularity due to
+the matter falling from the unstable interior part of the
+disk.
+II.
+CONSTANT RADII NULL GEODESICS
+AROUND THE KERR-TYPE NAKED
+SINGULARITY
+A rotating, massive naked singularity can be obtained
+from the Kerr metric in the Boyer-Lindquist coordinates
+(t, r, θ, φ) which reads (in the G = c = 1 units) as
+ds2 = −
+�
+1 − 2mr
+Σ
+�
+dt2 − 4mar sin2 θ
+Σ
+dtdφ + Σ
+∆dr2
++Σ dθ2 +
+�
+r2 + a2 + 2ma2r sin2 θ
+Σ
+�
+sin2 θdφ2, (1)
+arXiv:2301.13751v1  [gr-qc]  31 Jan 2023
+
+2
+where a :=
+J
+m is the dimensionfull rotation parameter
+which we shall take to be a > m.
+The two functions
+appearing in the metric are given as
+∆ ≡ r2 − 2mr + a2,
+Σ ≡ r2 + a2 cos2 θ.
+(2)
+For a < m, the larger root of ∆ = 0 is the event hori-
+zon located at rH = m + (m2 − a2)1/2, but in this work,
+∆ ̸= 0 and hence we have a naked rotating singular-
+ity. Our first task is to calculate the constant radii null
+and time-like geodesics in this background. The constant
+radii null geodesics are particularly important because
+they are unstable and carry away information about the
+environment of this strong gravitational region. In prac-
+tice one computes the shadow of this region as seen by a
+distant observer. Time-like geodesics are also important
+as they are traced by massive particles that constitute the
+accretion disk and change both the mass and the spin of
+the central object. Studying the evolution of the rotation
+parameter due to accretion of matter is our second task.
+For the spherical photon orbits, we need the radial part
+of the geodesic equation:
+Σ dr
+dλ = ±
+�
+R(r),
+(3)
+where λ is an affine parameter along the null geodesics.
+Assuming E ̸= 0, we can work with the dimensionless
+radial function R(x) := R(r)/(m4E2) in terms of dimen-
+sionless parameters
+R(x) := x4 + (α2 − l2 − q)x2 + 2x((α − l)2 + q) − α2q.(4)
+Here x := r/m, α := a/m, and l :=
+Lz
+mE where E is
+the conserved energy of the photon corresponding to the
+time-like Killing vector ξ(t) = ∂
+∂t; and Lz is the conserved
+z-component of the angular momentum of the photon
+related to the ξ(ϕ) =
+∂
+∂ϕ Killing vector, while q :=
+Q
+m2E2
+where Q is the Carter’s constant related to a symmetric
+rank two Killing tensor. Explicitly it reads
+Q := p2
+θ + cos2 θ
+� L2
+z
+sin2 θ − a2E2
+�
+,
+(5)
+and as a result
+q =
+p2
+θ
+m2E2 + cos2 θ
+�
+l2
+sin2 θ − α2
+�
+.
+(6)
+For constant radii orbits, Q ≥ 0, and the bound is sat-
+isfied for equatorial orbits [5–7]. There are two conditions
+on R(x) for spherical orbits
+R(x) = 0,
+dR(x)
+dx
+= 0,
+(7)
+which yield two physically viable equations [8]:
+l = −x3 − 3x2 + α2x + α2
+α(x − 1)
+,
+(8)
+q = −x3 �
+x3 − 6x2 + 9x − 4α2�
+α2(x − 1)2
+.
+(9)
+Now, we would like to investigate these two equations
+under various circumstances for α > 1.
+Figure 1: The orbit in the equatorial plane is plotted as a func-
+tion of the rotation parameter for the interval 1 < α < 1.6
+using (10). The radius of the orbit increases as the rotation
+parameter increases, which is an expected result for a retro-
+grade orbit.
+Figure 2: The l value of the equatorial orbit is plotted as a
+function of the rotation parameter for the interval 1 < α <
+1.6 using (8).
+The negative l value confirms that this is a
+retrograde orbit.
+A.
+Equatorial null Orbits
+On the equatorial plane, particles with a vanishing q
+can orbit [9]. For black holes with a rotation parameter
+α < 1, it is known that there are 3 solutions [8]. One
+of these lies inside the event horizon while the others are
+outside the horizon; and the latter correspond to pro-
+grade and retrograde orbits. On the other hand, for the
+naked singularity with a rotation parameter α > 1, the
+only real and non-zero solution of (9) for q = 0 is
+x− = 2 +
+�
+α +
+�
+α2 − 1
+�2/3
++
+�
+α +
+�
+α2 − 1
+�−2/3
+(10)
+which can be seen in Fig. (1). The photons that follow
+this orbit have a negative l value as shown in Fig. (2),
+and therefore x− is a retrograde orbit. The equatorial
+orbits set the innermost and the outermost limits of the
+generic spherical photon orbits. Hence, non-equatorial
+null orbits can exist only for the interval 0 < x < x− in
+this naked singularity spacetime.
+B.
+Polar Null Orbits
+Photons with a vanishing l and a positive q can have
+orbits on the polar plane. For a black hole with α < 1,
+
+4.5
+4.4
+4.3
+4.2
+4.1
+a
+1.1
+1.2
+1.3
+1.4
+1.5
+1.61
+1.1
+1.2
+1.3
+1.4
+1.5
+7.0
+1.6
+7.2
+-7.4
+7.6
+7.8
+-8.0F3
+Figure 3: For the vanishing l value, the corresponding rotation
+parameter as a function of radius is plotted for the interval
+0 < α < 3 using (11). The maximum value of the rotation
+parameter is αmax =
+�
+6
+√
+3 − 9. For higher values of rotation
+parameters, photons cannot reach to the polar plane.
+Figure 4: The polar orbits are drawn as a function of the
+rotation parameter in the interval 1 < α < 1.2.
+See that
+there are no polar orbits which has α >
+�
+6
+√
+3 − 9.
+we have already shown that there are 3 polar circular
+null orbits [8]. One of them corresponds to an orbit with
+a negative radius, therefore physically nonviable.
+The
+second solution lies inside the event horizon. The third
+solution lies outside the event horizon and corresponds
+to retrograde orbits. For the case of a naked singularity,
+(8) for l = 0 yields
+α(x) = x√3 − x
+√x + 1 ,
+(11)
+which vanishes at x = 0 and x = 3, and has a local
+maximum at x =
+√
+3 as shown in Fig. (3). The maximum
+value of the rotation parameter is αmax =
+�
+6
+√
+3 − 9 =
+1.17996 as was also found in [9]. The second derivative
+( d2R(x)
+dx2
+) for the physically viable orbits shows that while
+one of them is stable, the other one is unstable.
+In Fig. (4), the orbits on the polar plane are plotted
+as a function of the rotation parameter for the interval
+1 < α < 1.2. Note that there are no polar orbits for the
+spacetimes with α >
+�
+6
+√
+3 − 9.
+Let us note that the value
+�
+6
+√
+3 − 9 is an impor-
+tant limit on the rotation parameter:
+in the interval
+1 < α <
+�
+6
+√
+3 − 9, for generic spherical null orbits,
+the l value can be positive. This means that prograde,
+Figure 5: The marginally stable orbit as a function of the
+rotation parameter is plotted for the interval 1 < α < 1.6
+using (12).
+as well as retrograde, orbits are allowed.
+For a naked
+singularity with a rotation parameter higher than the
+maximum rotation parameter, α >
+�
+6
+√
+3 − 9, there are
+only retrograde orbits, prograde orbits simply disappear.
+This will have an observable consequence in the shadow
+of the naked singularity as we shall see.
+C.
+Marginally Stable null Orbits
+Marginally stable orbits are defined by the condition
+on the radial function as
+d2R
+dx2
+= 0 augmented with
+the conditions (7). On these orbits, one finds α(x) :=
+�
+(x − 3)x2 + 3x, [9], or
+xM = 1 + (α2 − 1)
+1
+3 ,
+(12)
+which is plotted in Fig.(5). Therefore, orbits with x <
+xM are stable and orbits with x > xM are unstable. The
+photons we can observe originate as a result of slight
+perturbations of the unstable orbits. Hence, stable orbits
+are not relevant for the shadow imaging. This has an
+important consequence.
+The orbits around the naked
+singularity located at x = 0 and the orbits around x =
+1 cannot have any visible effects on the image and the
+shadow.
+III.
+SHADOW OF A NAKED SINGULARITY
+In order to obtain the shadow, we will use the conven-
+tions of [10], [11]. For light rays with parameters l and
+q, we assume that there is an observer located at a point
+far away from the black hole with coordinates (r0, θ0, φ0)
+measuring the directions of these light rays. The coordi-
+nate φ0 can be taken as 0 using the axial symmetry of
+the spacetime for simplicity. θ0 is called the inclination
+angle of the observer. At large distances, for light rays
+one has
+dφ
+dt ≈
+l
+r2
+0 sin2 θ0
+,
+(13)
+
+a
+1.2
+1.0
+0.8
+0.6
+0.4
+0.2
+0.5
+1.0
+1.5
+2.0
+2.5
+3.02.4
+2.2
+2.0
+1.8
+1.6
+1.4
+1.2
+a
+1.05
+1.10
+1.15
+1.202.2
+2.0
+1.8
+1.6
+1.4
+1.2
+a
+1.1
+1.2
+1.3
+1.4
+1.5
+1.64
+and
+dθ
+dt ≈ ± 1
+r2
+0
+�
+q + α2 cos2 θ0 − l2 cot2 θ0.
+(14)
+Observe that the affine parameter is eliminated and the
+coordinate time t is used. Therefore, on the 2 dimensional
+image plane of the observer, we can define the impact
+parameters as
+X := −
+l
+sin θ0
+,
+(15)
+and
+Y := ±
+�
+q + α2 cos2 θ0 − l2 cot2 θ0.
+(16)
+Each photon coming from an orbit around the black hole
+due to a slight perturbation determines a point on the
+(X, Y ) plane of the image taken by the observer.
+A.
+Two Exemplary Cases
+1.
+Naked singularity with α = 1.1 < αmax
+For α = 1.1, using the results of previous sections,
+we can find spherical photon orbits with a radius in the
+interval
+0 < x < 4.08808.
+(17)
+The marginally stable orbit is located at
+xM = 1.59439,
+(18)
+so the unstable spherical photon orbits will be in the
+interval
+1.59439 < x < 4.08808.
+(19)
+Because of the fact that we have a rotation parameter
+which is smaller than αmax =
+�
+6
+√
+3 − 9, we can expect
+prograde orbits as well as retrograde orbits.
+The pro-
+grade orbits exist in the interval
+1.59439 < x < 2.2,
+(20)
+while the retrograde orbits are in the interval
+2.2 < x < 4.08808.
+(21)
+The shadow of the black hole is shown in Fig.(6) and
+Fig.(7). It is important to note that an observer located
+at the polar plane, θ0 = 0, cannot decide whether this is
+a Kerr black hole or Kerr-type naked singularity.
+Figure 6: The shadow image of the Kerr-type naked singular-
+ity located at the origin, with a rotation parameter α = 1.1 for
+an observer with the inclination angle θ0 = π
+2 . The rotation
+is in the counter-clockwise direction.
+Figure 7: The shadow image of the Kerr-type naked singular-
+ity located at the origin, with a rotation parameter α = 1.1
+for observers with different angles 0 < θ0 < π
+2 . An observer
+located at the polar plane, θ0 = 0, cannot decide whether this
+is a Kerr black hole or Kerr-type naked singularity.
+2.
+Naked singularity with αmax < α = 1.5
+For α = 1.5, we can find spherical photon orbits with
+a radius in the interval
+0 < x < 4.4260.
+(22)
+The marginally stable orbit is located at
+xM = 2.0772,
+(23)
+so the unstable spherical orbits will be in the interval
+2.0772 < x < 4.4260.
+(24)
+Because the rotation parameter is greater than αmax =
+�
+6
+√
+3 − 9, the l value can never change sign, there are no
+photons that can reach the polar plane, and all the orbits
+are retrograde. The shadow of the naked singularity is
+shown in Fig. (8) and Fig. (9).
+IV.
+CRITICAL INCLINATION ANGLE FOR
+NULL ORBITS
+In our previous work, [8], by combining the l (8) and
+q (9) expressions, we obtained a sextic polynomial and
+
+Y
+4
+2
+X
+2
+4
+6
+-2
+4Y
+2
+X
+-4
+-2
+2
+4
+-25
+Figure 8: The shadow image of the Kerr-type naked singular-
+ity with a rotation parameter α = 1.5 for an observer with the
+inclination angle π
+2 . There is no line with a negative X-value
+because there are no prograde orbit exists.
+Figure 9: The shadow image of the Kerr-type naked singu-
+larity with a rotation parameter α = 1.5 for observers with
+different inclination angles 0 < θ0 < π
+2 . There is no prograde
+orbit for this spacetime. Therefore, changing the inclination
+angle only affects the arc shape in the image.
+searched its analytical solutions for different conditions.
+In addition to the known equatorial and polar plane so-
+lutions, we found a new family of analytic solutions at
+the critical inclination angle. At this critical inclination
+angle, the sextic polynomial factors into a quadratic and
+a quartic part and becomes solvable by radicals. By us-
+ing the same method, we can find the critical inclination
+angle solutions for the α > 1 cases.
+The mentioned sextic polynomial equation is
+p(x) ≡ x6 − 6x5 + (9 + 2νu)x4 − 4ux3 − νu(6 − u)x2
++2νu2x + νu2 = 0,
+(25)
+Figure 10: The solution of the sextic polynomial is plotted as a
+function of the rotation parameter for the interval 1 < u < 2.
+where we have defined the dimensionless variables
+u := α2,
+ν :=
+q
+l2 + q .
+(26)
+In this section, we will call u to be the rotation parameter.
+One must solve this polynomial equation as x = x(u, ν)
+for the following intervals:
+0 < x,
+0 ≤ ν ≤ 1,
+1 < u.
+(27)
+To proceed further, it pays to define the following vari-
+ables which will simplify the final expressions:
+ν := ξ
+u,
+u := 1 + w3,
+(28)
+with 0 ≤ ξ and w ≥ 0.
+Even though a generic radi-
+cal solution to the sextic (25) is not possible, it can be
+shown that it reduces to a quadratic times a quartic at
+the following critical point for u > 1:
+ξcr =
+3(w + 1)3
+w(w + 5) + 7
+(29)
+and it becomes solvable.
+The four real solutions of
+this sextic polynomial are plotted in Fig.
+(10).
+Two
+of the solutions are degenerate with a vanishing second
+derivative and they are marginally stable orbits.
+One
+of the remaining solutions has a negative second deriva-
+tive and the other one has a positive second derivative,
+therefore they are stable and unstable critical orbits, re-
+spectively.
+The critical stable and unstable orbits are
+available only for spacetimes with a rotation parameter
+u < umax = 6
+√
+3 − 9 = 1.3923. The l and q values of
+these solutions can be seen in Fig. (11) and Fig. (12),
+respectively. The marginally stable orbits have a turning
+point and they can be prograde or retrograde. Likewise,
+the stable orbit can be prograde or retrograde. Yet, the
+unstable orbit is always retrograde. The Carter’s con-
+stants are non-zero, as expected.
+V.
+SPHERICAL TIMELIKE ORBITS AROUND
+THE NAKED SINGULARITY
+Let us now consider a massive particle with mass µ
+that moves on a spherical timelike orbit in the vicinity of
+
+3.5
+3.0
+MarginallyStableOrbit
+2.5
+CriticalStableOrbit
+2.0
+CriticalUnstableOrbit
+1.5
+u
+1.2
+1.4
+1.6
+1.8
+2.0Y
+4
+2
+X
+2
+3
+4
+5
+6
+7
+8
+-2Y
+4
+2
+X
+2
+3
+4
+5
+9
+8
+-2
+46
+Figure 11: The l value of the critical inclination angle orbit is
+plotted as a function of the rotation parameter for the interval
+1 < u < 2.
+Figure 12: The Carter’s constant of the critical inclination
+angle orbit as a function of the rotation parameter is plotted
+for the interval 1 < u < 2.
+the naked singularity. For the spherical timelike orbits,
+[12], the relevant geodesic equation is
+Σ dr
+dτ = ±
+�
+R(r),
+(30)
+where the radial function can be rearranged as R(x) :=
+R(r)/(m4µ2) which is given as
+R(x) := x2 �
+α2 � ˜E2 − 1
+�
+− l2 − q
+�
+− α2q
+(31)
++ 2x
+�
+(α ˜E − l)2 + q
+�
++
+� ˜E2 − 1
+�
+x4 + 2x3
+with l = Lz
+mµ, q =
+Q
+m2µ2 and ˜E = E
+µ . Note that in contrast
+to the null geodesics, the energy of the orbit is important,
+but the mass of the particle is not, hence we scaled out
+the mass of the particle as well as the mass of the central
+body.
+Two equations must be satisfied, R(x) = 0 and
+dR(x)
+dx
+= 0, for constant radius geodesics.
+There is a
+bifurcation of solutions: for x = 1, one has the following
+solutions
+l = 2
+�
+α2 + 1
+� ˜E2 − α2 + 1
+2α ˜E
+,
+(32)
+and
+q = α2 −
+�
+2 ˜E2 + 1
+�2
+4α2 ˜E2
+.
+(33)
+Figure 13: The radius of an equatorial retrograde orbit for a
+unit energy particle is plotted as a function of the rotation
+parameter for the interval 1 < α < 2 by using (36).
+On the other hand, for x ̸= 1, one has
+l =
+−1
+α2(x − 1) ×
+�
+α ˜E(α2 − x2)
+(34)
++
+�
+x
+�
+α3 + α(x − 2)x
+�2 �� ˜E2 − 1
+�
+x + 1
+��1/2�
+,
+and
+q =
+x2
+α3(−1 + x)2 ×
+�
+α3 ��
+2 ˜E2 − 1
+�
+x + 1
+�
+(35)
++2 ˜E
+�
+x
+�
+α3 + α(x − 2)x
+�2 �� ˜E2 − 1
+�
+x + 1
+��1/2
++αx
+�
+x
+� ˜E2(−((x − 4)x + 5)) + (x − 5)x + 8
+�
+− 4
+��
+.
+Next we shall analyze the unit energy solutions for which
+the equations are more transparent.
+A.
+Unit Energy Timelike Orbits
+For unit energy particles, ˜E = 1, from (34) and (35)
+one can obtain for the equatorial plane, q = 0,
+x = 2 + α ± 2
+√
+α + 1,
+(36)
+and the plus solution is plotted in Fig. (13) for the in-
+terval 1 < α < 2. The l value for this orbit is plotted
+in Fig. (14) for the same interval and it shows that this
+orbit is retrograde.
+On the polar plane, l = 0, we obtain
+α =
+�
+2x3/2 − x2,
+(37)
+which vanishes at x = 0 and x = 4 as can be seen in
+Fig. (15). This rotation parameter has a maximum at
+xmax =
+9
+4 with a value αmax =
+3
+√
+3
+4
+= 1.29904.
+For
+naked singularities with a rotation parameter less than
+this value, there could be prograde orbits as well as ret-
+rograde orbits for generic spherical orbits. It is impor-
+tant to observe that massive particles with a unit energy
+can co-rotate with the black hole for higher values of the
+rotation parameter than the photons whose maximum
+rotation parameter is αmax =
+�
+6
+√
+3 − 9. The spherical
+timelike orbits of the polar plane can be seen in Fig. (16).
+
+4
+MarginallyStableOrbits
+CriticalStableOrbit
+1.2
+1.8
+2.0
+u
+1.4
+1.6
+CriticalUnstableOrbit
+-2q
+40
+30
+MarginallyStableOrbits
+CriticalStableOrbit
+20
+CriticalUnstableOrbit
+10
+u
+1.2
+1.4
+1.6
+1.8
+2.0r
+7.5
+7.0
+6.5
+6.0
+a
+1.2
+1.4
+1.6
+1.8
+2.07
+Figure 14: The l value of an equatorial orbit for a unit energy
+particle is plotted as a function of the rotation parameter for
+the interval 1 < α < 2. The negative l values imply that this
+is a retrograde orbit.
+Figure 15: The rotation parameter as a function of the radius
+of the polar orbits is plotted for the interval 0 < x < 5.
+B.
+Generic Energy orbits on the Equatorial Plane
+When we solve the equation (35) for q = 0 with re-
+spect to the rotation parameter without assuming the
+unit energy condition, we get
+α =
+�
+4x + x2 �
+2 ˜E4x + ˜E2(5 − 3x) + x − 4
+�
+(38)
+−2
+�
+2 +
+� ˜E2 − 1
+�
+x
+� �
+˜E2x3 �� ˜E2 − 1
+�
+x + 1
+�� 1
+2
+.
+Two conclusions can be drawn from this relation. Firstly,
+for higher rotation parameter values, the radius of the
+spherical timelike orbit for particles of constant energy
+on the equatorial plane increases. Secondly, higher en-
+Figure 16: The polar orbits as a function of the rotation pa-
+rameter is plotted for the interval 1 < α < 1.5.
+Figure 17: The energy of the particles is plotted as a function
+of the radius for the interval 4.5 < x < 5 around a black hole
+with a rotation parameter α = 1.6. Higher energy particles
+follow orbits with smaller radii.
+ergy particles follow closer orbits to the naked singularity
+with a constant rotation parameter than the lower energy
+particles. As an example, for α = 1.6, the energy values
+as a function of the radius is plotted in Fig. (17).
+C.
+Generic Energy orbits on the Polar Plane
+The equation (34) for l = 0 yields
+α =
+�
+1
+˜E2(x + 1) − x
+×
+�
+x2 � ˜E2(−(x − 1)) + x − 2
+�
++2
+�
+˜E2x3 �� ˜E2 − 1
+�
+x + 1
+��� 1
+2
+.
+(39)
+Then, by using this relation, one can investigate the ro-
+tation parameter for different energy values.
+We have
+already shown that for a unit energy particle, there is a
+maximum possible rotation parameter αmax = 3
+√
+3
+4 . For
+˜E = 1.5, one finds αmax = 1.21002 and for ˜E = 2, one
+finds αmax = 1.19495. In conclusion, one can observe
+that for the high energy limit (for example ˜E = 100), the
+maximum value of the rotation parameter approaches
+to the maximum value of the photon case (αmax =
+�
+6
+√
+3 − 9) as expected.
+VI.
+ACCRETION INTO THE NAKED
+SINGULARITY
+A.
+Review of the α < 1 Case
+1.
+Special Circular Null and Timelike Orbits
+Accretion of matter and radiation around both non-
+rotating and rotating black holes is an extremely im-
+portant aspect of black hole physics in the strong field
+region, both from the vantage point of theory and obser-
+vation. For rotating black holes, one can consider thin
+
+1
+1.2
+1.4
+1.6
+1.8
+2.0
+a
+-4.9
+-5.0
+-5.1
+5.2
+5.3
+-5.4a
+1.2
+1.0
+0.8
+0.6
+0.4
+0.2
+2
+3
+4
+53.5
+3.0
+2.5
+StablePolarOrbt
+UnstablePolarOrbit
+2.0
+1.5
+a
+1.1
+1.2
+1.3
+1.4
+1.52
+E
+4
+3
+2
+4.6
+4.7
+4.8
+4.9
+5.08
+accretion disks around the equatorial plane. One may
+not be able to solve the whole disk plus the black hole
+system analytically in an exact form, but one can com-
+pute the effects of the accretion disk on the black hole
+by considering the properties of some special equatorial,
+circular null and timelike orbits. As matter and radia-
+tion fall into the black hole, the mass and the spin of the
+black hole increase as discussed by Bardeen [13] (without
+taking into account of the radiation) and later by Thorne
+[14] who considered the effects of the radiation. It turns
+out the retrograde photon orbits have a larger capture
+cross-section than that of prograde photon orbits, the
+latter generically spin up but the former spin down the
+black hole. Before investigating the accretion around a
+Kerr-type naked singularity, we would like to review the
+Kerr black hole case with α < 1.
+The radial timelike geodesic equation can be rewritten
+on the equatorial plane as
+dr
+dτ = ±r−3/2�
+R(r),
+(40)
+where the radial function can be rearrange to R(x) :=
+R(r)/(m4µ2) which is given as
+R(x) :=
+� ˜E2 − 1
+�
+x3 + α2 � ˜E2 − 1
+�
+x + 2(l − α ˜E)2
+−l2x + 2x2.
+(41)
+By using the circularity conditions, R(x) = 0 and
+dR(x)
+dx
+= 0, one can get
+l± = ±
+α2 + x2 ∓ 2α√x
+�
+±2αx3/2 + (x − 3)x2 ,
+˜E± =
+±α + (x − 2)√x
+�
+±2αx3/2 + (x − 3)x2 ,
+(42)
+where + represents prograde orbits while − represent
+retrograde orbits.
+It is important to state that circu-
+lar orbit solutions exist on the equatorial plane only if
+±2αx3/2 + (x − 3)x2 ≥ 0 and the equality is satisfied
+only by null orbits which is consistent with the left-hand
+side of the equations as these quantities represent angular
+momentum and energy per mass.
+The stability of these circular orbits is determined by
+the second derivative test:
+d2R(x)
+dx2
+> 0 for unstable or-
+bits, while d2R(x)
+dx2
+< 0 for stable ones. The special case
+d2R(x)
+dx2
+= 0 represents the innermost stable circular or-
+bit (ISCO) or the marginally stable orbit. This ISCO
+condition yields
+− 3α2 + x2 ± 8α√x − 6x = 0,
+(43)
+which has 4 solutions two of which are physically relevant
+and correspond to prograde and retrograde ISCOs. For
+the sake of simplicity, we will not provide the explicit
+expression here, but they are plotted in (18).
+Massive particles with ˜E > 1 follow unstable circular
+orbits on the equatorial plane and under a slight pertur-
+bation, they may escape to infinity or fall into the black
+Figure 18: The prograde and retrograde ISCOs, binding or-
+bits and photon orbits are plotted as a function of the rotation
+parameter for the interval 0 < α < 1.
+hole. Particles with ˜E < 1, under a perturbation, can
+only fall into the black hole. The special unstable orbits
+with ˜E = 1 are aptly called the binding orbits, and are
+located at
+xbind,± = ∓α + 2
+√
+1 ± α + 2
+(44)
+The prograde and retrograde ISCO, binding orbits and
+photon orbits can be seen in Fig. (18).
+2.
+Change in the spin of the black hole due to accretion
+Let us assume that there is a subextremal Kerr black
+hole with a thin accretion disk around its equator, and
+further assume that there are no gravitational or elec-
+tromagnetic radiation from the disk. Particles fall into
+the black hole under slight perturbations from the ISCO.
+These particles feed the black hole with mass δm =
+˜EISCO; and angular momentum δJ = lISCO.
+Under
+these assumptions, Bardeen [13] showed that a black hole
+which is initially static can be spinned up by particles on
+the accretion disk until it reaches the extremal rotation
+parameter α = 1. Later, Thorne [14] calculated the up-
+per limit as α = 0.998 by considering photons coming out
+of the accelerated particles. Here it turns out the capture
+cross-section of the retrograde orbits is larger than that
+of the prograde orbits and this fact does not allow the
+subextremal black hole to be spinned up to the extremal
+value.
+B.
+Accretion around Kerr-type Naked Singularity
+1.
+Special Circular Null and Timelike Orbits
+When the circularity conditions are applied for the
+radial part of the geodesic equations, R(x) = 0 and
+dR(x)
+dx
+= 0, for Kerr-type naked singularity spacetimes,
+α > 1, one get
+˜Eϵ =
+(x − 2) √x + ϵα
+�
+(x − 3) x2 + 2ϵαx3/2 ,
+(45)
+
+8
+ProgradePhotonOrbit
+ProgradeBindingOrbit
+ProgradeISCO
+RetrogradePhotonOrbit
+RetrogradeBindingOrbit
+RetrogradeISCO
+0.2
+0.4
+0.6
+0.8
+1.09
+Figure 19: The rotation parameter relation (48) is plotted for
+the interval 0 < x < 2.4. The maximum value of the rotation
+parameter is α =
+� 32
+27 and this means that it is possible
+to find orbits with zero or negative energy for the interval
+1 < α <
+� 32
+27.
+and
+lϵ = ϵ
+x2 + α2 − 2ϵα√x
+�
+(x − 3) x2 + 2ϵαx3/2 ,
+(46)
+where ϵ = +1 represents the prograde solutions while
+ϵ = −1 represents retrograde solutions. Because the ra-
+dial part of the geodesic equations has a quadratic de-
+pendence on ˜E and l, there should be a second solution.
+A straightforward calculation shows that the second so-
+lution is
+˜E′ = − ˜E,
+l′ = −l.
+(47)
+As already mentioned, the circular orbits exist only if
+(x − 3)x2 ± 2αx3/2 ≥ 0 and equality is satisfied only by
+null orbits. For spacetimes with α > 1, the equality is
+satisfied by a single orbit which is retrograde. In other
+words, there is no prograde null orbit on the equatorial
+plane.
+At this point, let us concentrate on an interesting prop-
+erty of the Kerr-type naked singularity spacetimes. For
+rotation parameter values which can be given as
+α (x) = (2 − x)√x,
+(48)
+the particles can rotate in their prograde orbits with zero
+energy. This is not possible for Kerr spacetimes because
+these orbits are located inside the event horizon. Yet, be-
+cause of the fact that there is no event horizon for naked
+singularity spacetimes, these orbits are relevant. Even
+more interestingly, there are orbits with radii smaller
+than zero energy orbits which are followed by particles
+with negative energy.
+By using 48, one can find that
+zero and negative energy orbits are possible in the range
+1 < α <
+�
+32
+27 = 1.08866 as can be seen in Fig. (19).
+In addition to these zero energy orbits, zero angular
+momentum orbits or ZAMOs are also possible for Kerr-
+type naked singularity spacetimes. For rotation parame-
+ter values
+α (x) = √x ±
+�
+x − x2,
+(49)
+Figure 20: The rotation parameter relation (49) is plotted for
+the interval 0 < x < 1.2. The maximum value of the rotation
+parameter is α =
+3
+√
+3
+4
+and this means that it is possible to
+find orbits with zero or negative angular momentum for the
+interval 1 < α < 3
+√
+3
+4 .
+the particles can rotate in their orbits with zero angular
+momentum. The relation (49) can be seen in Fig. (20).
+The maximum of the rotation parameter can be calcu-
+lated via 49 and it is α =
+�
+27
+16 = 1.29904. This means
+that it is possible to obtain orbits with zero or negative
+angular momenta for the interval 1 < α < 3
+√
+3
+4 .
+The special case, the innermost stable circular orbits
+(ISCO), correspond to the orbits which satisfy the equa-
+tion
+− 3α2 + x2 ± 8α√x − 6x = 0.
+(50)
+This condition accepts two solutions which correspond
+prograde and retrograde ISCO. For the sake of simplicity,
+we will not provide the explicit expression here.
+The other special case discussed for the Kerr black hole
+is the binding orbits.
+There exist prograde and retro-
+grade binding orbits for the Kerr-type naked singularity
+spacetime which can be given as
+xbind,± = 2 + α ∓ 2
+√
+α + 1.
+(51)
+The prograde and retrograde ISCO and binding orbits
+as well as retrograde photon orbits can be seen in Fig.
+(21). All orbits on the equatorial plane for both intervals
+0 < α < 1 and 1 < α < 1.5 are plotted in Fig. (22). The
+retrograde ISCO, binding orbit and photon orbit continue
+to exist for the naked singularity spacetimes. The pro-
+grade ISCO, binding orbit and the photon orbit merge
+at α = 1. The prograde photon orbit does not exist for
+α > 1. The prograde ISCO continues to exist but starts
+to move away from the singularity with an increasing ro-
+tation parameter. For the rotation parameter α = 3
+√
+3
+4 ,
+the particles on the prograde ISCO has l = 0. The pro-
+grade binding orbit also continues to exist but there is a
+discontinuity at α = 1 as can be seen in (22).
+2.
+Spinning down the Singularity
+An approach similar to the one developed by Bardeen
+[13] to investigate the effect of the particles in the ac-
+
+a
+1.0
+0.5
+0.5
+1.0
+1.5
+2.0
+0.5a
+1.2
+1.0
+0.8
+0.6
+0.4
+0.2
+0.2
+0.4
+0.6
+0.8
+1.0
+1.210
+Figure 21: The prograde and retrograde ISCO and binding
+orbits, and retrograde photon orbit are plotted as a function of
+the rotation parameter for the interval 1 < α < 1.5. Observe
+that the prograde orbits are closer the naked singularity than
+the retrograde orbits which means the latter have a larger
+capture cross-section. This fact plays an important role in
+the spinning-down effect.
+Figure 22: All equatorial orbits are plotted as a function of
+the rotation parameter for the interval 0 < α < 1.5.
+cretion disk on the Kerr black hole can be developed for
+the Kerr-type naked singularity. Let us assume there is a
+Kerr-type naked singularity with an accretion disk with
+a negligible thickness on the equatorial plane.
+Let us
+also assume gravitational and electromagnetic radiation
+of this disk is negligible. The gravitational field of the
+disk itself is much smaller than the gravitaional field of
+the singularity and therefore it is negligible. As a result,
+it can be assumed that particles on the disk follow circu-
+lar orbits as already discussed in the previous section.
+As a starting point, the change in the mass and the
+angular momentum of the Kerr-type naked singularity
+can be written as
+δJ
+δm = mf (α)
+(52)
+in order to denote their relation with the rotation param-
+eter. Before starting the calculation, in order to avoid
+complicated equations, let us define
+˜x := √xISCO.
+(53)
+In the previous section it was shown that, on the inner-
+Figure 23: Two rotation parameters, αp,1 and αp,2, corre-
+sponding to prograde orbit are plotted as a function of ˜x for
+the interval
+�
+2/3 ≤ ˜x ≤ 2.
+most stable circular orbit, the condition
+˜x4 − 6˜x2 + 8ϵα˜x − 3α2 = 0
+(54)
+should be satisfied. One can solve this equation with re-
+spect to the rotation parameter, α. For retrograde orbits,
+there are two solutions, one of which provides negative
+rotation parameter values and can be ignored. The phys-
+ically viable retrograde solution is
+αr (˜x) = 1
+3 ˜x
+��
+3˜x2 − 2 − 4
+�
+.
+(55)
+Note that for ˜x ≥ 3, one has α ≥ 1. For prograde orbits,
+there are two solutions and both of them are physically
+viable in their corresponding ranges. For the prograde
+orbit,
+αp,1 (˜x) = 1
+3 ˜x
+�
+4 −
+�
+3˜x2 − 2
+�
+,
+(56)
+the corresponding range becomes
+�
+2/3 ≤ ˜x ≤ 1, and in
+this range the rotation parameter is 1 ≤ α ≤
+�
+32
+27. The
+other prograde orbit is
+αp,2 (˜x) = 1
+3 ˜x
+�
+4 +
+�
+3˜x2 − 2
+�
+,
+(57)
+and it exists for
+�
+2/3 ≤ ˜x with a rotation parameter
+value
+�
+32
+27 ≤ α. Both rotation parameter solutions cor-
+responding to prograde orbit can be seen in Fig. (23).
+At this point, by using the assumption that infinitesi-
+mal changes in the mass and angular momentum of the
+naked singularity, δm and δJ , due to plunging parti-
+cles is equal to the energy and angular momentum of
+the particles following the innermost stable circular or-
+bit, δm = ˜EISCO and δJ = lISCO. One has
+f (α) = 1
+m
+δJ
+δm = 1
+m
+l±
+˜E±
+����
+˜x
+.
+(58)
+Let us start calculating the function f (α) for the ret-
+
+10
+ProgradeBindingOrbit
+8
+ProgradeISCO
+RetrogradePhotonOrbit
+RetrogradeBindingOrbit
+RetrogradeISCO
+a
+1.1
+1.2
+1.3
+1.4
+1.510
+8
+6
+0.2
+0.4
+0.6
+0.8
+1.0
+1.2
+1.4a
+5
+4
+Qp,1
+3
+Qp,2
+2
+1.0
+1.2
+1.4
+1.6
+1.8
+2.011
+rograde orbits first.
+f (α) =
+1
+m
+l−
+˜E−
+����
+˜x
+= −2˜x
+�
+12˜x2 + 4
+√
+3˜x2 − 2 − 7
+3
+√
+3˜x2 − 2
+= −2˜x
+3
+|2
+√
+3˜x2 − 2 + 1|
+√
+3˜x2 − 2
+= −2˜x
+3
+�
+2 +
+1
+√
+3˜x2 − 2
+�
+.
+(59)
+By using the relation J = αm2, one can get
+f (α) = 1
+m
+δJ
+δm =
+δα
+δ (ln m) + 2α.
+(60)
+With the help of 55, one has
+δαr =
+�2
+3
+� 3˜x2 − 1
+√
+3˜x2 − 2
+− 2
+��
+δ˜x.
+(61)
+Hence,
+f (α) − 2α = −2˜x
+3
+�
+2 +
+1
+√
+3˜x2 − 2
+�
+− 2α
+(62)
+= −2˜x
+3
+�
+−2 +
+1
+√
+3˜x2 − 2
++
+�
+3˜x2 − 2
+�
+,
+and
+δα
+δ (ln m) = 2
+3
+� 3˜x2 − 1
+√
+3˜x2 − 2
+− 2
+�
+δ˜x
+δ (ln m),
+(63)
+and by using 60 one can get
+δ (ln ˜x) = −δ (ln m) ,
+(64)
+of which the solution is ˜x = C/m where C is a constant
+and (55) becomes
+αr ( ˜m) = C
+3m
+��
+3 C2
+m2 − 2 − 4
+�
+.
+(65)
+The constant C can be found from the initial conditions
+with initial mass m0 and the initial rotation parameter
+α0. For instance, the retrograde ISCO is located at x =
+10.3759 for α0 = 1.5; and hence ˜x = 3.22116. So one
+finds C = 3.22116m0. After the falling of matter, at a
+later time, the relation turns into
+˜x = 3.22116m0
+m
+.
+(66)
+Therefore, one can write the rotation parameter relation
+(55) as a function of the mass of the singularity
+α (m) = 1.07372m0
+m
+��
+31.1277m2
+0
+m2
+− 2 − 4
+�
+,
+(67)
+and this relation is valid for 1.07372 ≥
+m
+m0 .
+So after
+accreting a mass of δm = 0.07372m0 the rotation pa-
+rameter is reduced to αr = 1 from its initial value of
+Figure 24: The rotation parameter is plotted as a function of
+the m/m0 for the interval 1 ≤
+m
+m0 ≤ 1.07372.
+αr = 1.5.
+Thus the particles following the retrograde
+ISCO quickly slow down the rotation of the singularity.
+This is a rather remarkable result: for example naked
+singularity with mass m0 = 1 kg and α0 = 1.5 only re-
+quires lass than 74 grams of matter to reduce α to the
+extremal rotation with an event horizon. The results can
+be seen in the Fig. (24).
+Now, we can concentrate on the prograde orbit. For
+prograde ISCO, from (58), one has
+f (αp,1) =
+1
+m
+l+
+˜E+
+����
+˜x
+= 2˜x
+3
+�
+2 +
+1
+√
+3˜x2 − 2
+�
+, (68)
+and
+f (αp,2) =
+1
+m
+l+
+˜E+
+����
+˜x
+= 2
+3 ˜x
+�
+2 −
+1
+√
+3˜x2 − 2
+�
+. (69)
+Let us first study the first prograde solution. Doing the
+computations as in the retrograde orbit case verbatim,
+we have
+f (αp,1) − 2αp,1 = 2˜x
+3
+�
+2 +
+1
+√
+3˜x2 − 2
+�
+− 2αp,1
+= 2˜x
+3
+�
+3˜x2 − 1 − 2
+√
+3˜x2 − 2
+√
+3˜x2 − 2
+�
+.
+(70)
+One can also find that
+f (αp,1) − 2αp,1 =
+δα
+δ (ln m)
+(71)
+= −2
+3
+�
+3˜x2 − 1 − 2
+√
+3˜x2 − 2
+√
+3˜x2 − 2
+�
+δ˜x
+δ (ln m).
+These two equations give
+δ (ln ˜x) = −δ (ln m) ,
+(72)
+of which the solution is ˜x = C/m which is valid in the
+interval
+�
+2/3 ≤ ˜x ≤ 1.
+Let us consider a Kerr-type
+naked singularity with initial mass m0 and initial rotation
+parameter α0 = 1.01. The prograde ISCO is represented
+by αp,1 for this case and it is located at x = 0.75192 and
+
+a
+1.5
+1.4
+1.3
+1.2
+1.1
+1.01
+1.02
+1.03
+1.04
+1.05
+1.06
+1.0712
+Figure 25: The rotation parameter is plotted with respect to
+m
+m0 for the interval 1 ≤
+m
+m0 ≤ 1.06202.
+hence ˜x = 0.867133. As a result, C = 0.867133m0. After
+matter accretion, the relation evolves to
+˜x = 0.867133m0
+m
+.
+(73)
+As a consequence, the rotation parameter as a function
+of mass becomes
+αp,1 (m) =
+0.289044
+�
+4 −
+�
+2.25576
+m2
+− 2
+�
+m
+,
+(74)
+which is valid in the interval 0.867133 ≤
+m
+m0 ≤ 1.06202.
+But accretion will not lead to decrease in mass, so one
+should restrict this interval to 1 ≤
+m
+m0 ≤ 1.06202. The
+evolution of the rotation parameter can be seen in Fig.
+(25). As can be seen, this prograde orbit tries to increase
+the rotation parameter value up to α =
+�
+32
+27.
+Now, as a final case, we would like to investigate the
+second prograde solution. Following similar steps, one
+arrives at ˜x = C/m.
+Assuming there is a Kerr-type
+naked singularity with an initial mass m0 and an ini-
+tial rotation parameter α0 = 1.5, the prograde ISCO can
+be found at x = 0.879352 and hence ˜x = 0.937738 and
+C = 0.937738m0. So one has
+˜x = 0.937738m0
+m
+.
+(75)
+As a consequence, the rotation parameter relation be-
+comes
+αp,2 (m) =
+0.312579
+��
+2.63806
+m2
+− 2 + 4
+�
+m
+,
+(76)
+which is valid for 1.14849 ≥
+m
+m0 . The evolution of the
+rotation parameter can be seen in Fig. (26). It is inter-
+esting to observe that the particles coming from a pro-
+grade orbit slow down the rotation. The final rotation
+parameter value of this process is α = 1.08866. After
+that value, the volution is governed by the solution of
+the second interval.
+To sum up, a Kerr-type naked singularity with an ini-
+tial mass m0 and an initial rotation parameter α0 = 1.5
+is slowed down by all falling particles. This slowing down
+Figure 26: The rotation parameter is plotted as a function of
+m
+m0 for the interval 1 <
+m
+m0 < 1.14849.
+Figure 27: The rotation parameter of a naked singularity with
+initial mass m0 and rotation parameter α0 = 1.05 is plotted
+for both prograde and retrograde orbits as a function of
+m
+m0
+for the interval 1 <
+m
+m0 < 1.00776.
+Figure 28: The rotation parameter of a naked singularity with
+initial mass m0 and rotation parameter α0 = 1.5 is plotted for
+both prograde and retrograde orbits as a function of
+m
+m0 for
+the interval 1 <
+m
+m0 < 1.14849. Observe that the retrograde
+orbits continue to spin down the central object even after the
+event horizon is formed.
+process continues until α =
+�
+32
+27. Below α =
+�
+32
+27, the
+particles from the prograde orbit start to spin the sin-
+gularity up while the particles from the retrograde orbit
+continue to slow it down.
+VII.
+CONCLUSIONS
+The Kerr metric is a solution to the vacuum Einstein
+equations [3] that is assumed to represent the gravita-
+tional field of all astrophysical black holes with only two
+hairs, its mass m and angular momentum J.
+Such a
+
+a
+1.08
+1.06
+1.04
+1.02
+mo
+1.01
+1.02
+1.03
+1.04
+1.05
+1.06a
+1.5
+1.4
+1.3
+1.2
+mo
+1.02
+1.04
+1.06
+1.08
+1.10
+1.12
+1.14a
+1.08
+1.06
+1.04
+1.02
+1.006
+mo
+1.002
+1.004a
+1.4
+1.2
+1.0
+0.8
+1.02
+1.04
+1.06
+1.08
+1.10
+1.12
+1.1413
+uniqueness is so remarkable that it also leads to a rather
+unique environment which can be observable due to the
+unstable nature the photon orbits, among which the con-
+stant radii orbits are particularly relevant. In this work,
+we have studied the Kerr-type naked singularity to un-
+derstand its shadow and its accretion. We found that a
+shadow image taken from the polar plane cannot distin-
+guish a naked Kerr-type singularity with a spin param-
+eter up to a maximum value (still above α = 1) from a
+Kerr black hole; while for naked singularities with spins
+higher than the maximum value, the shadow becomes
+quite distinct from that of the Kerr black hole.
+We have also studied the timelike orbits that are traced
+by massive particles around a naked singularity, and
+showed that the rapidly spinning singularity immediately
+slows down due the falling matter. Therefore, if a naked
+singularity is surrounded by a thin accretion disk around
+its equator, then it slows down and an event horizon is
+expected to form. In this process, the retrograde orbits
+play a dominant role as their capture cross-sections are
+larger than the prograde orbits.
+[1] R. Penrose, Gravitational collapse and space-time singu-
+larities, Phys. Rev. Lett. 14, 57-59 (1965).
+[2] R. Penrose, Gravitational collapse: The role of general
+relativity, Riv. Nuovo Cim. 1, 252-276 (1969).
+[3] R. P. Kerr, Gravitational Field of a Spinning Mass as
+an Example of Algebraically Special Metrics, Phys. Rev.
+Lett. 11, 237 (1963).
+[4] K. Akiyama et al. (Event Horizon Telescope), First M87
+event horizon telescope results. I. The shadow of the su-
+permassive black hole, Astrophys. J. 875, L1 (2019).
+[5] D. C. Wilkins, Bound geodesics in the Kerr metric, Phys.
+Rev. D 5, 814 (1972).
+[6] E. Teo, Spherical photon orbits around a kerr black hole,
+Gen. Relativ. Gravit. 35, 1909 (2003).
+[7] B. Carter, Global structure of the Kerr family of gravi-
+tational fields, Phys. Rev. 174, 1559 (1968).
+[8] A. Tavlayan and B. Tekin, Exact formulas for spherical
+photon orbits around Kerr black holes, Phys. Rev. D 102,
+104036 (2020).
+[9] D. Charbulák, Z. Stuchlík, Spherical photon orbits in the
+field of Kerr naked singularities, Eur. Phys. J. C 78, 879
+(2018).
+[10] V. P. Frolov and A. Zelnikov, Introduction to black hole
+physics, OUP Oxford (2011).
+[11] V. Patel, D. Tahelyani, A. B. Joshi et al., Light trajectory
+and shadow shape in the rotating naked singularity, Eur.
+Phys. J. C 82, 798 (2022).
+[12] A. Tavlayan and B. Tekin, Radii of spherical timelike
+orbits around Kerr black holes, Phys. Rev. D 104, 124059
+(2021).
+[13] J. M. Bardeen, Kerr Metric Black Holes, Nature 226,
+64-65 (1970).
+[14] K. S. Thorne, Disk accretion onto a black hole. 2. Evo-
+lution of the hole, Astrophys. J. 191, 507-520 (1974).
+
diff --git a/qNFST4oBgHgl3EQfOTiK/content/tmp_files/load_file.txt b/qNFST4oBgHgl3EQfOTiK/content/tmp_files/load_file.txt
new file mode 100644
index 0000000000000000000000000000000000000000..9f151dee6b7ab7f731e90d0c0ad205eb9e300087
--- /dev/null
+++ b/qNFST4oBgHgl3EQfOTiK/content/tmp_files/load_file.txt
@@ -0,0 +1,725 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf,len=724
+page_content='Kerr-type naked singularity: its shadow and accretion  Aydin Tavlayan1, ∗ and Bayram Tekin1, †  1Department of Physics,  Middle East Technical University, 06800 Ankara, Turkey  We study null and timelike constant radii geodesics in the environment of an over-spinning Kerr-  type naked singularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' We are particularly interested in two topics: first, the differences of the  shadows of the naked rotating singularity and the Kerr black hole;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' and second, the spinning down  effect of the particles falling from the accretion disk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Our findings are as follows: around the naked  singularity, the non-equatorial prograde orbits in the in Kerr black hole remain intact up to a  critical rotation parameter (α = 4  √  2  3  √  3) and cease to exist above this value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This has an important  consequence in the shadow of the naked singularity if the shadow is registered by an observer on  the rotation plane or close to it as the shadow cannot be distinguished from that of a Kerr black  hole viewed from the same angle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' We also show that the timelike retrograde orbits in the equatorial  plane immediately (after about an 8% increase in mass) reduce the spin parameter of the naked  singularity from larger values to α = 1 at which an event horizon appears.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This happens because  the retrograde orbits have a larger capture cross-section than the prograde ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  So if a naked  singularity happens to have an accretion disk, it will not remain naked for long, an event horizon  forms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  INTRODUCTION  Nature has a very efficient way in constraining some phys-  ical quantities;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' it just uses the square-roots, for exam-  ple the speed of any object is restricted to less than the  speed of light as the factor  �  1 − v2/c2 appears in rel-  ativistic physics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Similarly, in black hole physics, the  rotation of a black hole is restricted because the factor  √  1 − α2, with α being the dimensionless rotation param-  eter given in SI units in terms of the spin J and mass m  as α = cJ/(Gm2), appears in the location of the event  horizon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' If α > 1, there is no event horizon and the black  hole becomes a rotating, massive naked singularity, still  a solution to vacuum Einstein equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  As the stars, or star systems typically have α > 1 be-  fore a black hole is produced, it is clear that the angular  momentum of the collapsing matter must be depleted to  the values α < 1 to form a black hole, otherwise a naked  singularity is formed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Even though one can envisage ways  to deplete the angular momentum, we still do not know  how Nature solves this problem exactly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' [For example,  for our solar system α ≈ 35 and most of the contribution  comes from Jupiter’s angular momentum which is located  far away from the central mass, the Sun.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='] Some observed  black holes are rotating close to the extreme value α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  With the singularity theorem of Penrose [1], a singularity  is guaranteed to occur in a gravitational collapse under  reasonable assumptions on the energy-momentum tensor  of matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' However an event horizon is not guaranteed  to form, we only have an expectation dubbed as "the  cosmic censorship hypothesis" [2] which states that col-  lapsing matter do not form a naked singularity but it  does not state that naked singularities do not exist on  ∗Electronic address: aydint@metu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='tr  †Electronic address: btekin@metu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='tr  their own.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Due to this state of affairs, one is necessar-  ily curious about the observable differences in the causal  environment of a naked singularity and the Kerr black  hole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  For example, can a naked singularity mimic the  Kerr black hole [3] as far as its shadow [4] is concerned?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Can accretion of matter to a naked singularity spin down  its rotation in such a way that an event horizon forms ?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  In this work, we study various null and timelike orbits  around a naked singularity and make comparisons with  the Kerr black hole;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' we also give a detailed account of ac-  cretion of matter carrying angular momentum and mass  to a naked singularity assuming a thin equatorial accre-  tion disk about it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The lay-out of this paper is as follows: In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' II we  study the null spherical geodesics around the naked sin-  gularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' III we plot the shadows of various naked  singularities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' IV we concentrated on the null or-  bits at the critical inclination angle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' V we ex-  tended discussion to timelike geodesics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In Sec.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' VI we  give a detailed study of the accretion for both Kerr black  hole and the Kerr-type singularity for thin disks and show  the spinning-down effect for the naked singularity due to  the matter falling from the unstable interior part of the  disk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  CONSTANT RADII NULL GEODESICS  AROUND THE KERR-TYPE NAKED  SINGULARITY  A rotating, massive naked singularity can be obtained  from the Kerr metric in the Boyer-Lindquist coordinates  (t, r, θ, φ) which reads (in the G = c = 1 units) as  ds2 = −  �  1 − 2mr  Σ  �  dt2 − 4mar sin2 θ  Σ  dtdφ + Σ  ∆dr2  +Σ dθ2 +  �  r2 + a2 + 2ma2r sin2 θ  Σ  �  sin2 θdφ2, (1)  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='13751v1  [gr-qc]  31 Jan 2023  2  where a :=  J  m is the dimensionfull rotation parameter  which we shall take to be a > m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The two functions  appearing in the metric are given as  ∆ ≡ r2 − 2mr + a2,  Σ ≡ r2 + a2 cos2 θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (2)  For a < m, the larger root of ∆ = 0 is the event hori-  zon located at rH = m + (m2 − a2)1/2, but in this work,  ∆ ̸= 0 and hence we have a naked rotating singular-  ity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Our first task is to calculate the constant radii null  and time-like geodesics in this background.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The constant  radii null geodesics are particularly important because  they are unstable and carry away information about the  environment of this strong gravitational region.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In prac-  tice one computes the shadow of this region as seen by a  distant observer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Time-like geodesics are also important  as they are traced by massive particles that constitute the  accretion disk and change both the mass and the spin of  the central object.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Studying the evolution of the rotation  parameter due to accretion of matter is our second task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  For the spherical photon orbits, we need the radial part  of the geodesic equation:  Σ dr  dλ = ±  �  R(r),  (3)  where λ is an affine parameter along the null geodesics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Assuming E ̸= 0, we can work with the dimensionless  radial function R(x) := R(r)/(m4E2) in terms of dimen-  sionless parameters  R(x) := x4 + (α2 − l2 − q)x2 + 2x((α − l)2 + q) − α2q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (4)  Here x := r/m, α := a/m, and l :=  Lz  mE where E is  the conserved energy of the photon corresponding to the  time-like Killing vector ξ(t) = ∂  ∂t;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' and Lz is the conserved  z-component of the angular momentum of the photon  related to the ξ(ϕ) =  ∂  ∂ϕ Killing vector, while q :=  Q  m2E2  where Q is the Carter’s constant related to a symmetric  rank two Killing tensor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Explicitly it reads  Q := p2  θ + cos2 θ  � L2  z  sin2 θ − a2E2  �  ,  (5)  and as a result  q =  p2  θ  m2E2 + cos2 θ  �  l2  sin2 θ − α2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (6)  For constant radii orbits, Q ≥ 0, and the bound is sat-  isfied for equatorial orbits [5–7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' There are two conditions  on R(x) for spherical orbits  R(x) = 0,  dR(x)  dx  = 0,  (7)  which yield two physically viable equations [8]:  l = −x3 − 3x2 + α2x + α2  α(x − 1)  ,  (8)  q = −x3 �  x3 − 6x2 + 9x − 4α2�  α2(x − 1)2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (9)  Now, we would like to investigate these two equations  under various circumstances for α > 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 1: The orbit in the equatorial plane is plotted as a func-  tion of the rotation parameter for the interval 1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  using (10).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The radius of the orbit increases as the rotation  parameter increases, which is an expected result for a retro-  grade orbit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 2: The l value of the equatorial orbit is plotted as a  function of the rotation parameter for the interval 1 < α <  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6 using (8).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The negative l value confirms that this is a  retrograde orbit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Equatorial null Orbits  On the equatorial plane, particles with a vanishing q  can orbit [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For black holes with a rotation parameter  α < 1, it is known that there are 3 solutions [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' One  of these lies inside the event horizon while the others are  outside the horizon;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' and the latter correspond to pro-  grade and retrograde orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' On the other hand, for the  naked singularity with a rotation parameter α > 1, the  only real and non-zero solution of (9) for q = 0 is  x− = 2 +  �  α +  �  α2 − 1  �2/3  +  �  α +  �  α2 − 1  �−2/3  (10)  which can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The photons that follow  this orbit have a negative l value as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (2),  and therefore x− is a retrograde orbit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The equatorial  orbits set the innermost and the outermost limits of the  generic spherical photon orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Hence, non-equatorial  null orbits can exist only for the interval 0 < x < x− in  this naked singularity spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Polar Null Orbits  Photons with a vanishing l and a positive q can have  orbits on the polar plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For a black hole with α < 1,  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='61  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0F3  Figure 3: For the vanishing l value, the corresponding rotation  parameter as a function of radius is plotted for the interval  0 < α < 3 using (11).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The maximum value of the rotation  parameter is αmax =  �  6  √  3 − 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For higher values of rotation  parameters, photons cannot reach to the polar plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 4: The polar orbits are drawn as a function of the  rotation parameter in the interval 1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  See that  there are no polar orbits which has α >  �  6  √  3 − 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  we have already shown that there are 3 polar circular  null orbits [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' One of them corresponds to an orbit with  a negative radius, therefore physically nonviable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The  second solution lies inside the event horizon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The third  solution lies outside the event horizon and corresponds  to retrograde orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For the case of a naked singularity,  (8) for l = 0 yields  α(x) = x√3 − x  √x + 1 ,  (11)  which vanishes at x = 0 and x = 3, and has a local  maximum at x =  √  3 as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The maximum  value of the rotation parameter is αmax =  �  6  √  3 − 9 =  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='17996 as was also found in [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The second derivative  ( d2R(x)  dx2  ) for the physically viable orbits shows that while  one of them is stable, the other one is unstable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  In Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (4), the orbits on the polar plane are plotted  as a function of the rotation parameter for the interval  1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Note that there are no polar orbits for the  spacetimes with α >  �  6  √  3 − 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Let us note that the value  �  6  √  3 − 9 is an impor-  tant limit on the rotation parameter:  in the interval  1 < α <  �  6  √  3 − 9, for generic spherical null orbits,  the l value can be positive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This means that prograde,  Figure 5: The marginally stable orbit as a function of the  rotation parameter is plotted for the interval 1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  using (12).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  as well as retrograde, orbits are allowed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  For a naked  singularity with a rotation parameter higher than the  maximum rotation parameter, α >  �  6  √  3 − 9, there are  only retrograde orbits, prograde orbits simply disappear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  This will have an observable consequence in the shadow  of the naked singularity as we shall see.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Marginally Stable null Orbits  Marginally stable orbits are defined by the condition  on the radial function as  d2R  dx2  = 0 augmented with  the conditions (7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' On these orbits, one finds α(x) :=  �  (x − 3)x2 + 3x, [9], or  xM = 1 + (α2 − 1)  1  3 ,  (12)  which is plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='(5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Therefore, orbits with x <  xM are stable and orbits with x > xM are unstable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The  photons we can observe originate as a result of slight  perturbations of the unstable orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Hence, stable orbits  are not relevant for the shadow imaging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This has an  important consequence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The orbits around the naked  singularity located at x = 0 and the orbits around x =  1 cannot have any visible effects on the image and the  shadow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  SHADOW OF A NAKED SINGULARITY  In order to obtain the shadow, we will use the conven-  tions of [10], [11].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For light rays with parameters l and  q, we assume that there is an observer located at a point  far away from the black hole with coordinates (r0, θ0, φ0)  measuring the directions of these light rays.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The coordi-  nate φ0 can be taken as 0 using the axial symmetry of  the spacetime for simplicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' θ0 is called the inclination  angle of the observer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' At large distances, for light rays  one has  dφ  dt ≈  l  r2  0 sin2 θ0  ,  (13)  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='05  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='10  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='15  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='202.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='64  and  dθ  dt ≈ ± 1  r2  0  �  q + α2 cos2 θ0 − l2 cot2 θ0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (14)  Observe that the affine parameter is eliminated and the  coordinate time t is used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Therefore, on the 2 dimensional  image plane of the observer, we can define the impact  parameters as  X := −  l  sin θ0  ,  (15)  and  Y := ±  �  q + α2 cos2 θ0 − l2 cot2 θ0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (16)  Each photon coming from an orbit around the black hole  due to a slight perturbation determines a point on the  (X, Y ) plane of the image taken by the observer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Two Exemplary Cases  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Naked singularity with α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1 < αmax  For α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1, using the results of previous sections,  we can find spherical photon orbits with a radius in the  interval  0 < x < 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08808.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (17)  The marginally stable orbit is located at  xM = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='59439,  (18)  so the unstable spherical photon orbits will be in the  interval  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='59439 < x < 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08808.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (19)  Because of the fact that we have a rotation parameter  which is smaller than αmax =  �  6  √  3 − 9, we can expect  prograde orbits as well as retrograde orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The pro-  grade orbits exist in the interval  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='59439 < x < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2,  (20)  while the retrograde orbits are in the interval  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2 < x < 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08808.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (21)  The shadow of the black hole is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (6) and  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='(7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' It is important to note that an observer located  at the polar plane, θ0 = 0, cannot decide whether this is  a Kerr black hole or Kerr-type naked singularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 6: The shadow image of the Kerr-type naked singular-  ity located at the origin, with a rotation parameter α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1 for  an observer with the inclination angle θ0 = π  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The rotation  is in the counter-clockwise direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 7: The shadow image of the Kerr-type naked singular-  ity located at the origin, with a rotation parameter α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  for observers with different angles 0 < θ0 < π  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' An observer  located at the polar plane, θ0 = 0, cannot decide whether this  is a Kerr black hole or Kerr-type naked singularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Naked singularity with αmax < α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  For α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5, we can find spherical photon orbits with  a radius in the interval  0 < x < 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4260.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (22)  The marginally stable orbit is located at  xM = 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0772,  (23)  so the unstable spherical orbits will be in the interval  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0772 < x < 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4260.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (24)  Because the rotation parameter is greater than αmax =  �  6  √  3 − 9, the l value can never change sign, there are no  photons that can reach the polar plane, and all the orbits  are retrograde.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The shadow of the naked singularity is  shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (8) and Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  CRITICAL INCLINATION ANGLE FOR  NULL ORBITS  In our previous work, [8], by combining the l (8) and  q (9) expressions, we obtained a sextic polynomial and  Y  4  2  X  2  4  6  2  4Y  2  X  4  2  2  4  25  Figure 8: The shadow image of the Kerr-type naked singular-  ity with a rotation parameter α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5 for an observer with the  inclination angle π  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' There is no line with a negative X-value  because there are no prograde orbit exists.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 9: The shadow image of the Kerr-type naked singu-  larity with a rotation parameter α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5 for observers with  different inclination angles 0 < θ0 < π  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' There is no prograde  orbit for this spacetime.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Therefore, changing the inclination  angle only affects the arc shape in the image.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  searched its analytical solutions for different conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  In addition to the known equatorial and polar plane so-  lutions, we found a new family of analytic solutions at  the critical inclination angle.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' At this critical inclination  angle, the sextic polynomial factors into a quadratic and  a quartic part and becomes solvable by radicals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' By us-  ing the same method, we can find the critical inclination  angle solutions for the α > 1 cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The mentioned sextic polynomial equation is  p(x) ≡ x6 − 6x5 + (9 + 2νu)x4 − 4ux3 − νu(6 − u)x2  +2νu2x + νu2 = 0,  (25)  Figure 10: The solution of the sextic polynomial is plotted as a  function of the rotation parameter for the interval 1 < u < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  where we have defined the dimensionless variables  u := α2,  ν :=  q  l2 + q .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (26)  In this section, we will call u to be the rotation parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  One must solve this polynomial equation as x = x(u, ν)  for the following intervals:  0 < x,  0 ≤ ν ≤ 1,  1 < u.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (27)  To proceed further, it pays to define the following vari-  ables which will simplify the final expressions:  ν := ξ  u,  u := 1 + w3,  (28)  with 0 ≤ ξ and w ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Even though a generic radi-  cal solution to the sextic (25) is not possible, it can be  shown that it reduces to a quadratic times a quartic at  the following critical point for u > 1:  ξcr =  3(w + 1)3  w(w + 5) + 7  (29)  and it becomes solvable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The four real solutions of  this sextic polynomial are plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (10).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Two  of the solutions are degenerate with a vanishing second  derivative and they are marginally stable orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  One  of the remaining solutions has a negative second deriva-  tive and the other one has a positive second derivative,  therefore they are stable and unstable critical orbits, re-  spectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The critical stable and unstable orbits are  available only for spacetimes with a rotation parameter  u < umax = 6  √  3 − 9 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3923.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The l and q values of  these solutions can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (11) and Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (12),  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The marginally stable orbits have a turning  point and they can be prograde or retrograde.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Likewise,  the stable orbit can be prograde or retrograde.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Yet, the  unstable orbit is always retrograde.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The Carter’s con-  stants are non-zero, as expected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  SPHERICAL TIMELIKE ORBITS AROUND  THE NAKED SINGULARITY  Let us now consider a massive particle with mass µ  that moves on a spherical timelike orbit in the vicinity of  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  MarginallyStableOrbit  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  CriticalStableOrbit  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  CriticalUnstableOrbit  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  u  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0Y  4  2  X  2  3  4  5  6  7  8  2Y  4  2  X  2  3  4  5  9  8  2  46  Figure 11: The l value of the critical inclination angle orbit is  plotted as a function of the rotation parameter for the interval  1 < u < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 12: The Carter’s constant of the critical inclination  angle orbit as a function of the rotation parameter is plotted  for the interval 1 < u < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  the naked singularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For the spherical timelike orbits,  [12], the relevant geodesic equation is  Σ dr  dτ = ±  �  R(r),  (30)  where the radial function can be rearranged as R(x) :=  R(r)/(m4µ2) which is given as  R(x) := x2 �  α2 � ˜E2 − 1  �  − l2 − q  �  − α2q  (31)  + 2x  �  (α ˜E − l)2 + q  �  +  � ˜E2 − 1  �  x4 + 2x3  with l = Lz  mµ, q =  Q  m2µ2 and ˜E = E  µ .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Note that in contrast  to the null geodesics, the energy of the orbit is important,  but the mass of the particle is not, hence we scaled out  the mass of the particle as well as the mass of the central  body.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Two equations must be satisfied, R(x) = 0 and  dR(x)  dx  = 0, for constant radius geodesics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  There is a  bifurcation of solutions: for x = 1, one has the following  solutions  l = 2  �  α2 + 1  � ˜E2 − α2 + 1  2α ˜E  ,  (32)  and  q = α2 −  �  2 ˜E2 + 1  �2  4α2 ˜E2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (33)  Figure 13: The radius of an equatorial retrograde orbit for a  unit energy particle is plotted as a function of the rotation  parameter for the interval 1 < α < 2 by using (36).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  On the other hand, for x ̸= 1, one has  l =  −1  α2(x − 1) ×  �  α ˜E(α2 − x2)  (34)  +  �  x  �  α3 + α(x − 2)x  �2 �� ˜E2 − 1  �  x + 1  ��1/2�  ,  and  q =  x2  α3(−1 + x)2 ×  �  α3 ��  2 ˜E2 − 1  �  x + 1  �  (35)  +2 ˜E  �  x  �  α3 + α(x − 2)x  �2 �� ˜E2 − 1  �  x + 1  ��1/2  +αx  �  x  � ˜E2(−((x − 4)x + 5)) + (x − 5)x + 8  �  − 4  ��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Next we shall analyze the unit energy solutions for which  the equations are more transparent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Unit Energy Timelike Orbits  For unit energy particles, ˜E = 1, from (34) and (35)  one can obtain for the equatorial plane, q = 0,  x = 2 + α ± 2  √  α + 1,  (36)  and the plus solution is plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (13) for the in-  terval 1 < α < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The l value for this orbit is plotted  in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (14) for the same interval and it shows that this  orbit is retrograde.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  On the polar plane, l = 0, we obtain  α =  �  2x3/2 − x2,  (37)  which vanishes at x = 0 and x = 4 as can be seen in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (15).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This rotation parameter has a maximum at  xmax =  9  4 with a value αmax =  3  √  3  4  = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='29904.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  For  naked singularities with a rotation parameter less than  this value, there could be prograde orbits as well as ret-  rograde orbits for generic spherical orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' It is impor-  tant to observe that massive particles with a unit energy  can co-rotate with the black hole for higher values of the  rotation parameter than the photons whose maximum  rotation parameter is αmax =  �  6  √  3 − 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The spherical  timelike orbits of the polar plane can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (16).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  4  MarginallyStableOrbits  CriticalStableOrbit  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  u  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  CriticalUnstableOrbit  2q  40  30  MarginallyStableOrbits  CriticalStableOrbit  20  CriticalUnstableOrbit  10  u  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0r  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='07  Figure 14: The l value of an equatorial orbit for a unit energy  particle is plotted as a function of the rotation parameter for  the interval 1 < α < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The negative l values imply that this  is a retrograde orbit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 15: The rotation parameter as a function of the radius  of the polar orbits is plotted for the interval 0 < x < 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Generic Energy orbits on the Equatorial Plane  When we solve the equation (35) for q = 0 with re-  spect to the rotation parameter without assuming the  unit energy condition, we get  α =  �  4x + x2 �  2 ˜E4x + ˜E2(5 − 3x) + x − 4  �  (38)  −2  �  2 +  � ˜E2 − 1  �  x  � �  ˜E2x3 �� ˜E2 − 1  �  x + 1  �� 1  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Two conclusions can be drawn from this relation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Firstly,  for higher rotation parameter values, the radius of the  spherical timelike orbit for particles of constant energy  on the equatorial plane increases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Secondly, higher en-  Figure 16: The polar orbits as a function of the rotation pa-  rameter is plotted for the interval 1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 17: The energy of the particles is plotted as a function  of the radius for the interval 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5 < x < 5 around a black hole  with a rotation parameter α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Higher energy particles  follow orbits with smaller radii.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  ergy particles follow closer orbits to the naked singularity  with a constant rotation parameter than the lower energy  particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' As an example, for α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6, the energy values  as a function of the radius is plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (17).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Generic Energy orbits on the Polar Plane  The equation (34) for l = 0 yields  α =  �  1  ˜E2(x + 1) − x  ×  �  x2 � ˜E2(−(x − 1)) + x − 2  �  +2  �  ˜E2x3 �� ˜E2 − 1  �  x + 1  ��� 1  2  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (39)  Then, by using this relation, one can investigate the ro-  tation parameter for different energy values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  We have  already shown that for a unit energy particle, there is a  maximum possible rotation parameter αmax = 3  √  3  4 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For  ˜E = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5, one finds αmax = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='21002 and for ˜E = 2, one  finds αmax = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='19495.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In conclusion, one can observe  that for the high energy limit (for example ˜E = 100), the  maximum value of the rotation parameter approaches  to the maximum value of the photon case (αmax =  �  6  √  3 − 9) as expected.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  ACCRETION INTO THE NAKED  SINGULARITY  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Review of the α < 1 Case  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Special Circular Null and Timelike Orbits  Accretion of matter and radiation around both non-  rotating and rotating black holes is an extremely im-  portant aspect of black hole physics in the strong field  region, both from the vantage point of theory and obser-  vation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For rotating black holes, one can consider thin  1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  a  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='9  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  2  3  4  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  StablePolarOrbt  UnstablePolarOrbit  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='52  E  4  3  2  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='7  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='9  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08  accretion disks around the equatorial plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' One may  not be able to solve the whole disk plus the black hole  system analytically in an exact form, but one can com-  pute the effects of the accretion disk on the black hole  by considering the properties of some special equatorial,  circular null and timelike orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' As matter and radia-  tion fall into the black hole, the mass and the spin of the  black hole increase as discussed by Bardeen [13] (without  taking into account of the radiation) and later by Thorne  [14] who considered the effects of the radiation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' It turns  out the retrograde photon orbits have a larger capture  cross-section than that of prograde photon orbits, the  latter generically spin up but the former spin down the  black hole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Before investigating the accretion around a  Kerr-type naked singularity, we would like to review the  Kerr black hole case with α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The radial timelike geodesic equation can be rewritten  on the equatorial plane as  dr  dτ = ±r−3/2�  R(r),  (40)  where the radial function can be rearrange to R(x) :=  R(r)/(m4µ2) which is given as  R(x) :=  � ˜E2 − 1  �  x3 + α2 � ˜E2 − 1  �  x + 2(l − α ˜E)2  −l2x + 2x2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (41)  By using the circularity conditions, R(x) = 0 and  dR(x)  dx  = 0, one can get  l± = ±  α2 + x2 ∓ 2α√x  �  ±2αx3/2 + (x − 3)x2 ,  ˜E± =  ±α + (x − 2)√x  �  ±2αx3/2 + (x − 3)x2 ,  (42)  where + represents prograde orbits while − represent  retrograde orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  It is important to state that circu-  lar orbit solutions exist on the equatorial plane only if  ±2αx3/2 + (x − 3)x2 ≥ 0 and the equality is satisfied  only by null orbits which is consistent with the left-hand  side of the equations as these quantities represent angular  momentum and energy per mass.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The stability of these circular orbits is determined by  the second derivative test:  d2R(x)  dx2  > 0 for unstable or-  bits, while d2R(x)  dx2  < 0 for stable ones.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The special case  d2R(x)  dx2  = 0 represents the innermost stable circular or-  bit (ISCO) or the marginally stable orbit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This ISCO  condition yields  − 3α2 + x2 ± 8α√x − 6x = 0,  (43)  which has 4 solutions two of which are physically relevant  and correspond to prograde and retrograde ISCOs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For  the sake of simplicity, we will not provide the explicit  expression here, but they are plotted in (18).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Massive particles with ˜E > 1 follow unstable circular  orbits on the equatorial plane and under a slight pertur-  bation, they may escape to infinity or fall into the black  Figure 18: The prograde and retrograde ISCOs, binding or-  bits and photon orbits are plotted as a function of the rotation  parameter for the interval 0 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  hole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Particles with ˜E < 1, under a perturbation, can  only fall into the black hole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The special unstable orbits  with ˜E = 1 are aptly called the binding orbits, and are  located at  xbind,± = ∓α + 2  √  1 ± α + 2  (44)  The prograde and retrograde ISCO, binding orbits and  photon orbits can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (18).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Change in the spin of the black hole due to accretion  Let us assume that there is a subextremal Kerr black  hole with a thin accretion disk around its equator, and  further assume that there are no gravitational or elec-  tromagnetic radiation from the disk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Particles fall into  the black hole under slight perturbations from the ISCO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  These particles feed the black hole with mass δm =  ˜EISCO;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' and angular momentum δJ = lISCO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Under  these assumptions, Bardeen [13] showed that a black hole  which is initially static can be spinned up by particles on  the accretion disk until it reaches the extremal rotation  parameter α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Later, Thorne [14] calculated the up-  per limit as α = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='998 by considering photons coming out  of the accelerated particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Here it turns out the capture  cross-section of the retrograde orbits is larger than that  of the prograde orbits and this fact does not allow the  subextremal black hole to be spinned up to the extremal  value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Accretion around Kerr-type Naked Singularity  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Special Circular Null and Timelike Orbits  When the circularity conditions are applied for the  radial part of the geodesic equations, R(x) = 0 and  dR(x)  dx  = 0, for Kerr-type naked singularity spacetimes,  α > 1, one get  ˜Eϵ =  (x − 2) √x + ϵα  �  (x − 3) x2 + 2ϵαx3/2 ,  (45)  8  ProgradePhotonOrbit  ProgradeBindingOrbit  ProgradeISCO  RetrogradePhotonOrbit  RetrogradeBindingOrbit  RetrogradeISCO  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='09  Figure 19: The rotation parameter relation (48) is plotted for  the interval 0 < x < 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The maximum value of the rotation  parameter is α =  � 32  27 and this means that it is possible  to find orbits with zero or negative energy for the interval  1 < α <  � 32  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  and  lϵ = ϵ  x2 + α2 − 2ϵα√x  �  (x − 3) x2 + 2ϵαx3/2 ,  (46)  where ϵ = +1 represents the prograde solutions while  ϵ = −1 represents retrograde solutions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Because the ra-  dial part of the geodesic equations has a quadratic de-  pendence on ˜E and l, there should be a second solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  A straightforward calculation shows that the second so-  lution is  ˜E′ = − ˜E,  l′ = −l.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (47)  As already mentioned, the circular orbits exist only if  (x − 3)x2 ± 2αx3/2 ≥ 0 and equality is satisfied only by  null orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For spacetimes with α > 1, the equality is  satisfied by a single orbit which is retrograde.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In other  words, there is no prograde null orbit on the equatorial  plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  At this point, let us concentrate on an interesting prop-  erty of the Kerr-type naked singularity spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For  rotation parameter values which can be given as  α (x) = (2 − x)√x,  (48)  the particles can rotate in their prograde orbits with zero  energy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This is not possible for Kerr spacetimes because  these orbits are located inside the event horizon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Yet, be-  cause of the fact that there is no event horizon for naked  singularity spacetimes, these orbits are relevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Even  more interestingly, there are orbits with radii smaller  than zero energy orbits which are followed by particles  with negative energy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  By using 48, one can find that  zero and negative energy orbits are possible in the range  1 < α <  �  32  27 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08866 as can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (19).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  In addition to these zero energy orbits, zero angular  momentum orbits or ZAMOs are also possible for Kerr-  type naked singularity spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For rotation parame-  ter values  α (x) = √x ±  �  x − x2,  (49)  Figure 20: The rotation parameter relation (49) is plotted for  the interval 0 < x < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The maximum value of the rotation  parameter is α =  3  √  3  4  and this means that it is possible to  find orbits with zero or negative angular momentum for the  interval 1 < α < 3  √  3  4 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  the particles can rotate in their orbits with zero angular  momentum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The relation (49) can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (20).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The maximum of the rotation parameter can be calcu-  lated via 49 and it is α =  �  27  16 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='29904.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This means  that it is possible to obtain orbits with zero or negative  angular momenta for the interval 1 < α < 3  √  3  4 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The special case, the innermost stable circular orbits  (ISCO), correspond to the orbits which satisfy the equa-  tion  − 3α2 + x2 ± 8α√x − 6x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (50)  This condition accepts two solutions which correspond  prograde and retrograde ISCO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For the sake of simplicity,  we will not provide the explicit expression here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  The other special case discussed for the Kerr black hole  is the binding orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  There exist prograde and retro-  grade binding orbits for the Kerr-type naked singularity  spacetime which can be given as  xbind,± = 2 + α ∓ 2  √  α + 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (51)  The prograde and retrograde ISCO and binding orbits  as well as retrograde photon orbits can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (21).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' All orbits on the equatorial plane for both intervals  0 < α < 1 and 1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5 are plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The  retrograde ISCO, binding orbit and photon orbit continue  to exist for the naked singularity spacetimes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The pro-  grade ISCO, binding orbit and the photon orbit merge  at α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The prograde photon orbit does not exist for  α > 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The prograde ISCO continues to exist but starts  to move away from the singularity with an increasing ro-  tation parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For the rotation parameter α = 3  √  3  4 ,  the particles on the prograde ISCO has l = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The pro-  grade binding orbit also continues to exist but there is a  discontinuity at α = 1 as can be seen in (22).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Spinning down the Singularity  An approach similar to the one developed by Bardeen  [13] to investigate the effect of the particles in the ac-  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='210  Figure 21: The prograde and retrograde ISCO and binding  orbits, and retrograde photon orbit are plotted as a function of  the rotation parameter for the interval 1 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Observe  that the prograde orbits are closer the naked singularity than  the retrograde orbits which means the latter have a larger  capture cross-section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This fact plays an important role in  the spinning-down effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 22: All equatorial orbits are plotted as a function of  the rotation parameter for the interval 0 < α < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  cretion disk on the Kerr black hole can be developed for  the Kerr-type naked singularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Let us assume there is a  Kerr-type naked singularity with an accretion disk with  a negligible thickness on the equatorial plane.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Let us  also assume gravitational and electromagnetic radiation  of this disk is negligible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The gravitational field of the  disk itself is much smaller than the gravitaional field of  the singularity and therefore it is negligible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' As a result,  it can be assumed that particles on the disk follow circu-  lar orbits as already discussed in the previous section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  As a starting point, the change in the mass and the  angular momentum of the Kerr-type naked singularity  can be written as  δJ  δm = mf (α)  (52)  in order to denote their relation with the rotation param-  eter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Before starting the calculation, in order to avoid  complicated equations, let us define  ˜x := √xISCO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (53)  In the previous section it was shown that, on the inner-  Figure 23: Two rotation parameters, αp,1 and αp,2, corre-  sponding to prograde orbit are plotted as a function of ˜x for  the interval  �  2/3 ≤ ˜x ≤ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  most stable circular orbit, the condition  ˜x4 − 6˜x2 + 8ϵα˜x − 3α2 = 0  (54)  should be satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' One can solve this equation with re-  spect to the rotation parameter, α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For retrograde orbits,  there are two solutions, one of which provides negative  rotation parameter values and can be ignored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The phys-  ically viable retrograde solution is  αr (˜x) = 1  3 ˜x  ��  3˜x2 − 2 − 4  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (55)  Note that for ˜x ≥ 3, one has α ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For prograde orbits,  there are two solutions and both of them are physically  viable in their corresponding ranges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For the prograde  orbit,  αp,1 (˜x) = 1  3 ˜x  �  4 −  �  3˜x2 − 2  �  ,  (56)  the corresponding range becomes  �  2/3 ≤ ˜x ≤ 1, and in  this range the rotation parameter is 1 ≤ α ≤  �  32  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The  other prograde orbit is  αp,2 (˜x) = 1  3 ˜x  �  4 +  �  3˜x2 − 2  �  ,  (57)  and it exists for  �  2/3 ≤ ˜x with a rotation parameter  value  �  32  27 ≤ α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Both rotation parameter solutions cor-  responding to prograde orbit can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (23).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  At this point, by using the assumption that infinitesi-  mal changes in the mass and angular momentum of the  naked singularity, δm and δJ , due to plunging parti-  cles is equal to the energy and angular momentum of  the particles following the innermost stable circular or-  bit, δm = ˜EISCO and δJ = lISCO.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' One has  f (α) = 1  m  δJ  δm = 1  m  l±  ˜E±  ����  ˜x  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (58)  Let us start calculating the function f (α) for the ret-  10  ProgradeBindingOrbit  8  ProgradeISCO  RetrogradePhotonOrbit  RetrogradeBindingOrbit  RetrogradeISCO  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='510  8  6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4a  5  4  Qp,1  3  Qp,2  2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='6  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='011  rograde orbits first.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  f (α) =  1  m  l−  ˜E−  ����  ˜x  = −2˜x  �  12˜x2 + 4  √  3˜x2 − 2 − 7  3  √  3˜x2 − 2  = −2˜x  3  |2  √  3˜x2 − 2 + 1|  √  3˜x2 − 2  = −2˜x  3  �  2 +  1  √  3˜x2 − 2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (59)  By using the relation J = αm2, one can get  f (α) = 1  m  δJ  δm =  δα  δ (ln m) + 2α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (60)  With the help of 55, one has  δαr =  �2  3  � 3˜x2 − 1  √  3˜x2 − 2  − 2  ��  δ˜x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (61)  Hence,  f (α) − 2α = −2˜x  3  �  2 +  1  √  3˜x2 − 2  �  − 2α  (62)  = −2˜x  3  �  −2 +  1  √  3˜x2 − 2  +  �  3˜x2 − 2  �  ,  and  δα  δ (ln m) = 2  3  � 3˜x2 − 1  √  3˜x2 − 2  − 2  �  δ˜x  δ (ln m),  (63)  and by using 60 one can get  δ (ln ˜x) = −δ (ln m) ,  (64)  of which the solution is ˜x = C/m where C is a constant  and (55) becomes  αr ( ˜m) = C  3m  ��  3 C2  m2 − 2 − 4  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (65)  The constant C can be found from the initial conditions  with initial mass m0 and the initial rotation parameter  α0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For instance, the retrograde ISCO is located at x =  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3759 for α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' and hence ˜x = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='22116.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' So one  finds C = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='22116m0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' After the falling of matter, at a  later time, the relation turns into  ˜x = 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='22116m0  m  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (66)  Therefore, one can write the rotation parameter relation  (55) as a function of the mass of the singularity  α (m) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='07372m0  m  ��  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1277m2  0  m2  − 2 − 4  �  ,  (67)  and this relation is valid for 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='07372 ≥  m  m0 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  So after  accreting a mass of δm = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='07372m0 the rotation pa-  rameter is reduced to αr = 1 from its initial value of  Figure 24: The rotation parameter is plotted as a function of  the m/m0 for the interval 1 ≤  m  m0 ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='07372.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  αr = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Thus the particles following the retrograde  ISCO quickly slow down the rotation of the singularity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  This is a rather remarkable result: for example naked  singularity with mass m0 = 1 kg and α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5 only re-  quires lass than 74 grams of matter to reduce α to the  extremal rotation with an event horizon.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The results can  be seen in the Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (24).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Now, we can concentrate on the prograde orbit.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' For  prograde ISCO, from (58), one has  f (αp,1) =  1  m  l+  ˜E+  ����  ˜x  = 2˜x  3  �  2 +  1  √  3˜x2 − 2  �  , (68)  and  f (αp,2) =  1  m  l+  ˜E+  ����  ˜x  = 2  3 ˜x  �  2 −  1  √  3˜x2 − 2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (69)  Let us first study the first prograde solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Doing the  computations as in the retrograde orbit case verbatim,  we have  f (αp,1) − 2αp,1 = 2˜x  3  �  2 +  1  √  3˜x2 − 2  �  − 2αp,1  = 2˜x  3  �  3˜x2 − 1 − 2  √  3˜x2 − 2  √  3˜x2 − 2  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (70)  One can also find that  f (αp,1) − 2αp,1 =  δα  δ (ln m)  (71)  = −2  3  �  3˜x2 − 1 − 2  √  3˜x2 − 2  √  3˜x2 − 2  �  δ˜x  δ (ln m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  These two equations give  δ (ln ˜x) = −δ (ln m) ,  (72)  of which the solution is ˜x = C/m which is valid in the  interval  �  2/3 ≤ ˜x ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Let us consider a Kerr-type  naked singularity with initial mass m0 and initial rotation  parameter α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='01.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The prograde ISCO is represented  by αp,1 for this case and it is located at x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='75192 and  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='01  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='03  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='05  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0712  Figure 25: The rotation parameter is plotted with respect to  m  m0 for the interval 1 ≤  m  m0 ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06202.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  hence ˜x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='867133.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' As a result, C = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='867133m0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' After  matter accretion, the relation evolves to  ˜x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='867133m0  m  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (73)  As a consequence, the rotation parameter as a function  of mass becomes  αp,1 (m) =  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='289044  �  4 −  �  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='25576  m2  − 2  �  m  ,  (74)  which is valid in the interval 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='867133 ≤  m  m0 ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06202.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  But accretion will not lead to decrease in mass, so one  should restrict this interval to 1 ≤  m  m0 ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06202.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The  evolution of the rotation parameter can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (25).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' As can be seen, this prograde orbit tries to increase  the rotation parameter value up to α =  �  32  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Now, as a final case, we would like to investigate the  second prograde solution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Following similar steps, one  arrives at ˜x = C/m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Assuming there is a Kerr-type  naked singularity with an initial mass m0 and an ini-  tial rotation parameter α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5, the prograde ISCO can  be found at x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='879352 and hence ˜x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='937738 and  C = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='937738m0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' So one has  ˜x = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='937738m0  m  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  (75)  As a consequence, the rotation parameter relation be-  comes  αp,2 (m) =  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='312579  ��  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='63806  m2  − 2 + 4  �  m  ,  (76)  which is valid for 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='14849 ≥  m  m0 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The evolution of the  rotation parameter can be seen in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (26).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' It is inter-  esting to observe that the particles coming from a pro-  grade orbit slow down the rotation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The final rotation  parameter value of this process is α = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08866.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' After  that value, the volution is governed by the solution of  the second interval.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  To sum up, a Kerr-type naked singularity with an ini-  tial mass m0 and an initial rotation parameter α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  is slowed down by all falling particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' This slowing down  Figure 26: The rotation parameter is plotted as a function of  m  m0 for the interval 1 <  m  m0 < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='14849.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 27: The rotation parameter of a naked singularity with  initial mass m0 and rotation parameter α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='05 is plotted  for both prograde and retrograde orbits as a function of  m  m0  for the interval 1 <  m  m0 < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='00776.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Figure 28: The rotation parameter of a naked singularity with  initial mass m0 and rotation parameter α0 = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5 is plotted for  both prograde and retrograde orbits as a function of  m  m0 for  the interval 1 <  m  m0 < 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='14849.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Observe that the retrograde  orbits continue to spin down the central object even after the  event horizon is formed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  process continues until α =  �  32  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Below α =  �  32  27, the  particles from the prograde orbit start to spin the sin-  gularity up while the particles from the retrograde orbit  continue to slow it down.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  VII.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  CONCLUSIONS  The Kerr metric is a solution to the vacuum Einstein  equations [3] that is assumed to represent the gravita-  tional field of all astrophysical black holes with only two  hairs, its mass m and angular momentum J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Such a  a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02  mo  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='01  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='03  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='05  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='5  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='3  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  mo  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='10  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='12  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='14a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='006  mo  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='002  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='004a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='2  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='8  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='02  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='04  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='06  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='08  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='10  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='12  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='1413  uniqueness is so remarkable that it also leads to a rather  unique environment which can be observable due to the  unstable nature the photon orbits, among which the con-  stant radii orbits are particularly relevant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In this work,  we have studied the Kerr-type naked singularity to un-  derstand its shadow and its accretion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' We found that a  shadow image taken from the polar plane cannot distin-  guish a naked Kerr-type singularity with a spin param-  eter up to a maximum value (still above α = 1) from a  Kerr black hole;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' while for naked singularities with spins  higher than the maximum value, the shadow becomes  quite distinct from that of the Kerr black hole.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  We have also studied the timelike orbits that are traced  by massive particles around a naked singularity, and  showed that the rapidly spinning singularity immediately  slows down due the falling matter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Therefore, if a naked  singularity is surrounded by a thin accretion disk around  its equator, then it slows down and an event horizon is  expected to form.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' In this process, the retrograde orbits  play a dominant role as their capture cross-sections are  larger than the prograde orbits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  [1] R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Penrose, Gravitational collapse and space-time singu-  larities, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' 14, 57-59 (1965).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  [2] R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Penrose, Gravitational collapse: The role of general  relativity, Riv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Nuovo Cim.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' 1, 252-276 (1969).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  [3] R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Kerr, Gravitational Field of a Spinning Mass as  an Example of Algebraically Special Metrics, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Lett.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' 11, 237 (1963).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  [4] K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Akiyama et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' (Event Horizon Telescope), First M87  event horizon telescope results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' The shadow of the su-  permassive black hole, Astrophys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' 875, L1 (2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  [5] D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' Wilkins, Bound geodesics in the Kerr metric, Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content='  Rev.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
+page_content=' D 5, 814 (1972).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
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+page_content=' Teo, Spherical photon orbits around a kerr black hole,  Gen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qNFST4oBgHgl3EQfOTiK/content/2301.13751v1.pdf'}
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+Peculiar band geometry induced giant shift current in ferroelectric SnTe monolayer
+Gan Jin1 and Lixin He1, 2, ∗
+1Key Laboratory of Quantum Information, University of Science and Technology of China,
+Hefei, Anhui, 230026, People’s Republic of China
+2Institute of Artificial Intelligence, Hefei Comprehensive National Science Center,
+Hefei, Anhui, 230026, People’s Republic of China
+The bulk photovoltaic effect (BPVE) refers to the phenomenon of generating photocurrent or
+photovoltage in homogeneous noncentrosymmetric materials under illumination, and the intrinsic
+contribution to the BPVE is known as the shift current effect.
+We calculate the shift current
+conductivities of the ferroelectric SnTe monolayer using first-principles methods. We find that the
+monolayer SnTe has giant shift-current conductivity near the valley points. More remarkably, the
+linear optical absorption coefficient at this energy is very small, and therefore leads to an enormous
+Glass coefficient that is four orders of magnitude larger than that of BaTiO3. The unusual shift-
+current effects are further investigated using a three-band model. We find that the giant shift current
+conductivities and Glass coefficient are induced by the nontrivial energy band geometries near the
+valley points, where the shift-vector diverges. This is a prominent example that the band geometry
+can play essential roles in the fundamental properties of solids.
+INTRODUCTION
+The study of BPVE has a long history [1–3], and re-
+cently it has attracted great renewed interest because it
+potentially allows the energy conversion efficiency to sur-
+pass the Shockley–Queisser limit [4, 5]. The shift-current
+effects are believed to be the main intrinsic contribution
+to the BPVE [3, 6], which can be used as an alternative to
+the photocurrent generated by traditional semiconductor
+p–n junctions [7, 8]. It has been demonstrated that the
+photovoltage generated by shift-current effects can be far
+above the band gap [9–12].
+The high priority of current studies in the field is to find
+novel materials that have high shift-current conductivi-
+ties. Cook et al. proposed design principles of the shift
+current materials through an effective two-dimensional
+model and successfully applied them to monochalco-
+genide GeS [8]. In addition to conventional ferroelectric
+materials [13, 14], special attention has been given to
+Weyl semimetals because of the unique topological na-
+ture of band structures. Osterhoudt et al. discovered a
+huge mid-infrared BPVE in the Weyl semimetal TaAs,
+which is linked to the topological properties of the ma-
+terial [15].
+Type-II Weyl semimetal TaIrTe4 has been
+found to have a huge optical response, and the shift cur-
+rent is related to the divergent Berry curvature at the
+Weyl nodes [16]. Ahn et al. theoretically studied the low-
+frequency properties of BPVEs in topological semimet-
+als, and revealed the relation between the shift current as
+well as the injection current and the quantum geometry
+of the material near the Weyl point [17].
+In this work, we investigate the nonlinear optical prop-
+erties of the two-dimensional ferroelectric material SnTe
+monolayer [18] using first-principles methods. We find
+that it has giant shift current conductivities near the
+valley points.
+More remarkably, the linear optical ab-
+sorption coefficient at this energy is very small, which
+leads to an enormous Glass coefficient of four orders of
+magnitude larger than that of bulk BaTiO3 [1, 5, 19].
+We develop a minimal three-band model to analyze the
+mechanism of the giant shift-current effect in the SnTe
+monolayer. We find that the giant shift-current effects
+are induced by the nontrivial band structure geometry,
+where the shift-vector diverges at the valley point. We
+further show that the giant shift-current is related to the
+derivatives of the imaginary part of the quantum geo-
+metric tensor near the point. The mechanism is different
+from the previous works on the Weyl semimetals [17],
+and therefore opens a new play ground for the fascinat-
+ing physical properties that are determined by the band
+structure geometries.
+RESULTS
+Crystal structure
+In 2016, Chang et al. [18] discovered that the SnTe
+monolayer has robust in-plane ferroelectricity with a
+Curie temperature as high as 270 K, which is greatly
+enhanced from its bulk value of 98 K. As a member
+of the Group IV monochalcogenide (MX, M = Ge, Sn,
+Pb; X = S, Se, Te) family, the SnTe monolayer, which
+has great potential in miniaturized ferroelectric devices,
+has been extensively studied experimentally [20] and via
+first-principles calculations [21–23]. The structure of the
+SnTe monolayer is shown in Fig. 1, which has a hinge-
+like structure similar to that of phosphorene. The SnTe
+monolayer has a Pmn21 space group with mirror sym-
+metry (Mxz) and glide mirror symmetry (G). It has an
+in-plane ferroelectricity along the x-axis [20–23].
+The lack of inversion symmetry suggests that the SnTe
+monolayer should have shift-current effects.
+We per-
+form first-principles calculations to investigate the shift-
+current effects in the SnTe monolayer.
+Details of the
+calculations are presented in the METHODS section.
+arXiv:2301.13391v1  [cond-mat.mtrl-sci]  31 Jan 2023
+
+2
+FIG. 1. (a) Top view, (b) side view along the x direction and
+(c) side view along the y direction of the crystal structure of
+the SnTe monolayer. Sn and Te atoms are shown using blue
+and red spheres, respectively. The unit cell is indicated by
+the dashed rectangle in (a). (d) The band gap between the
+lowest conduction band and the highest valence band in the
+Brillouin zone, where k0, ¯k0 k1 and ¯k1 are the valley points.
+Band structure and shift current conductivities
+The band structures of SnTe monolayer with and with-
+out spin-orbit coupling (SOC) are shown in Fig.S1 of the
+Supplementary Information (SI). There are four valley
+points of the band structure in the first Brillouin zone.
+Two valley points, k0=(0.41, 0.0), k1=(0.0, 0.41), in di-
+rect coordinates, are on the Γ-X line and Γ-Y line re-
+spectively, whereas the other two valley points are ob-
+tained by the time inversion symmetry of the above two
+k-points, i.e., ¯k0 = −k0 and ¯k1 = −k1, as shown in Fig.
+1(d). The introduction of SOC only slightly changes the
+positions of the valley points (see Fig. S1 in SI).
+The break of inversion symmetry would lead to the
+shift current in the SnTe monolayer, i.e., a nonlinear dc
+photocurrent under illumination [1–3],
+Ja = 2σabc(0; ω, −ω)Eb(ω)Ec(−ω),
+(1)
+where σabc(0; ω, −ω) is the shift-current conductivity,
+and a (b, c)=x, y, z are the crystal axes. Due to the
+2D monolayer structure, we do not consider the current
+in the z-direction. Similarly, we do not consider the elec-
+tric field applied in the z-direction. Because of the mirror
+symmetry Mxz of the SnTe monolayer, only σxxx, σxyy,
+and σyxy=σyyx are nonzero (see the SI).
+We investigate the shift-current conductivities by using
+first-principles calculations [3, 24–26], and the numerical
+results are consistent with the above symmetry analy-
+sis.
+The 3D-like conductivities are obtained assuming
+an active single-layer thickness of 3.12 ˚A[25, 27].
+Al-
+though quantitatively, the results with and without SOC
+are somehow different, but the inclusion of SOC does
+not affect the main results and conclusions of the paper
+(see Fig. S4 in SI). Therefore, we only discuss the re-
+sults without SOC here, and the analysis can be equally
+applied to the results with SOC.
+Figure 2(a) depicts σyxy, which is the largest compo-
+nent of the shift-current conductivities. σyxy has three
+distinct peaks at 0.87 eV, 1.24 eV, and 2.18 eV, respec-
+tively, in the energy interval 0∼4 eV. The highest peak
+is at ℏω0=0.87 eV, with σyxy
+3D =481.89 µA/V2, which is
+significantly larger than the known high BPVE material
+GeS of the order of 150 µA/V2 and 250 µA/V2 in state-
+of-the-art Si-based solar cells [25, 27, 28].
+To experimentally explore this effect, we may apply
+light with an electric field polarized along the [110] direc-
+tion, and measure the shift current along the y direction,
+which gives
+jy = 2σyxyEx(ω)Ey(−ω).
+(2)
+In previous works [7, 8, 25], it has been suggested that
+to have a large shift current, a large joint density of states
+(JDOS) is necessary, which has been used as a design
+principle in finding materials with a large shift current.
+Surprisingly, we find that the JDOS at ℏω0=0.87 eV is
+extremely small as plotted in Fig.
+S2 in the SI. As a
+consequence, the absorption coefficients are expected to
+be small at this photon energy. Indeed, the absorption
+coefficient α[110] is also very small around ℏω0=0.87 eV,
+as shown in Fig. 2(b). What is more amazing is that
+the absorption coefficient αyy=0 at this energy, strongly
+against our intuition, given that σyxy is huge.
+The above results have important physical conse-
+quences. We compute the Glass coefficient [1, 7, 9, 24]
+gabc = α−1σabc,
+(3)
+and the result of gyxy is shown in Fig. 2(c). gyxy has
+a sharp peak at ℏω0=0.87 eV, due to the giant σyxy
+and small α[110]. The calculated Glass coefficient gyxy
+of the SnTe monolayer at ℏω0=0.87 eV is 5.2 × 10−5
+cm·V−1 [27], which is four orders of magnitude higher
+than g31=3×10−9 cm·V−1 of the bulk (001)-oriented
+BaTiO3 crystal [1, 5, 19]. The Glass coefficient g plays
+essential roles in the shift current related physical prop-
+erties. For example, the photovoltaic field generated by
+the shift current [1, 5] can be estimated as,
+Epv ≈
+g
+φ(µτ)pv
+ℏω
+e ,
+(4)
+where φ is the quantum yield, ℏω is the incident photon
+energy and µ and τ are the mobility and lifetime of the
+carriers responsible for photoconductivity. A very large
+g will lead to a very large photovoltaic field Epv, as in
+this case, the “leaking” current due to photoconductivity
+is much weaker than the shift current. The photovoltaic
+power conversion efficiency is also closely related to the
+Glass coefficient [1].
+
+(a)
+(q)
+Sn
+Te
+(c)
+(d)
+0.4
+4
+X
+0.2
+3
+Ko
+0.0
+Z
+-0.2
+2
+k1
+X
+-0.4
+-0.4-0.2 0.0
+0.2
+0.4
+kx3
+0
+1
+2
+3
+4
+0
+200
+400
+yxy
+3D  ( A/V2)
+(a)
+0
+1
+2
+3
+4
+0.0
+2.5
+5.0
+7.5
+[110] (105cm
+1)
+(b)
+0
+1
+2
+3
+4
+ (eV)
+0
+2
+4
+gyxy (10
+5 cm V
+1)
+(c)
+FIG. 2. (a) Shift current conductivity σyxy
+3D of the SnTe mono-
+layer. There are three peaks at 0.87, 1.24, and 2.18 eV, re-
+spectively. The highest peak is at 0.87 eV. (b) The absorp-
+tion coefficient α[110] and (c) the Glass coefficient of the SnTe
+monolayer, respectively.
+The Glass coefficient has a sharp
+peak at 0.87 eV.
+DISCUSSION
+Origin of the giant shift current in yxy direction
+It is particularly interesting and important to explore
+the underlaying mechanism of the giant shift-current con-
+ductivity and Glass coefficient in the SnTe monolayer.
+The shift-current tensor is given by [3],
+σabc(0; ω, −ω) =πe3
+ℏ2
+�
+dk
+8π3
+�
+n,m
+fnm Im
+�
+Iabc
+mn
++Iacb
+mn
+�
+δ (ωmn − ω) ,
+(5)
+where fnm=fn − fm and ℏωnm=Em − En are differences
+between Fermi occupation factors and band energies, re-
+spectively. Iabc
+mn = rb
+mnrc
+nm;a, where ra
+nm is the inter-band
+dipole matrix, and rb
+nm;a is the generalized derivative of
+the dipole matrix, i.e.,
+ra
+nm = (1 − δnm)Aa
+nm,
+(6)
+ra
+nm;b = ∂bra
+nm − i
+�
+Ab
+nn − Ab
+mm
+�
+ra
+nm.
+(7)
+Here, Aa
+nm is the non-Abelian Berry connection. More
+detailed calculations of ra
+nm and ra
+nm;b are described in
+Methods. Although ra
+nm and rb
+nm;a are gauge dependent,
+their norm |ra
+nm| and |rb
+nm;a|, as well as Iabc
+mn are gauge
+invariant [25]. Note that ra
+nm and rb
+nm;a and Iabc
+mn are all
+k dependent, but here we drop the k index for simplicity.
+We calculate �
+n,m fnm Im [Iyxy
+mn + Iyyx
+mn ] δ (ωmn − ω0) ,
+for ℏω0=0.87 eV, in the first BZ [see Fig. S3(a) of SI].
+We find the contribution solely comes from the transition
+between the highest valence band and the lowest conduc-
+tion band, around the valley points k0 and ¯k0. Because
+only the valley points contribute to the optical transi-
+tions at ℏω0, the corresponding JDOS and linear absorp-
+tion coefficient is very small. Furthermore, as shown in
+Fig. S3(b) of SI, Ivc = Im [Iyxy
+vc
++ Iyyx
+vc ], where v and c,
+are the highest valence band and the lowest conduction
+band, has a sharp peak at k0, which leads to the giant
+shift-current conductivity.
+Figure 3(a) depicts the norm of rx
+vc and ry
+vc along ky
+passing through k0, which are shown in red and blue solid
+lines respectively. We see |rx
+vc| has a maximum at ky=0,
+whereas |ry
+vc|=0 at k0 due to the mirror symmetry Mxz.
+However, as seen from Fig. 3(a), |ry
+vc| changes rapidly
+along ky around k0. One may speculate that ry
+vc may
+have a large partial derivative (Eq. 7) along ky at the
+valley point. Indeed, as shown in Fig. 3(b), |ry
+cv;y| has a
+peak at k0. We plot Ivc in Fig. 3(c). Interestingly, we
+find that Ivc ≈ |rx
+vc||ry
+vc;y| around k0 (See SI). Both rx
+vc
+and ry
+cv;y reach the maximum at k0, which lead to the
+giant Ivc.
+Three-band model
+To gain a deeper insight into the physics, we construct
+a minimal three-band model around the valley point k0,
+H(k) = H0+Aδkx+Bδky +Cδk2
+x+Dδkxδky +Eδk2
+y, (8)
+up to the quadratic terms of δk , where δk=k−k0. More
+specifically, δkx=kx − 0.41, δky=ky. We therefore do not
+distinguish ky and δky below. In the model, the 1st-band
+is the highest valence band, whereas the 2nd-band and
+3rd-band correspond to the lowest two conduction bands
+in the DFT calculations. We fit the Hamiltonian matrix
+H(k) and velocity matrix vmn(k) from DFT calculations
+around k0. The fitted parameters of the model are given
+in the SI.
+We first (numerically) calculate |rx
+12|, |ry
+12;y|, and I12
+of the three-band model, and the results are com-
+pared with those of DFT calculations in Fig. 3(a),(b),
+
+4
+0.05
+0.00
+0.05
+0
+2
+4
+6
+|ra
+vc| (Å)
+(a)
+DFT |rx
+vc|
+DFT |ry
+vc|
+Model |rx
+vc|
+Model |ry
+vc|
+0.05
+0.00
+0.05
+0
+50
+100
+150
+|ry
+cv; y| (Å2)
+(b)
+DFT
+Model
+0.05
+0.00
+0.05
+k-PATH (0.41, -0.07) to (0.41, 0.07)
+0
+500
+1000
+Ivc (Å3)
+(c)
+DFT
+Model
+FIG. 3.
+(a) The norm of dipole matrix rx
+vc and ry
+vc along ky,
+where v and c are highest valence band and lowest conduction
+band, respectively. (b) The norm of the generalized derivative
+of dipole matrix, ry
+cv;y, along ky. (d) The Ivc=Im [Iyxy
+vc
++ Iyyx
+vc ]
+along ky. The results obtained from DFT and model calcula-
+tions are shown in solid and dashed lines, respectively.
+and (c), respectively. The three-band model can semi-
+quantitatively reproduce the results of DFT calculations,
+and the discrepancies are due to neglecting other bands.
+Around k0, the wave functions of the three-band model
+can be solved analytically via a second order pertur-
+bation theory, and therefore ra
+nm and ra
+nm;b can also
+be calculated analytically.
+Especially, at k0 we have
+vx
+nm(k0) = Anm and vy
+nm(k0) = Bnm, therefore
+rx
+nm(k0) = Anm
+iωnm
+,
+ry
+nm(k0) = Bnm
+iωnm
+.
+(9)
+Because A12̸=0, and B12=0, which is actually imposed
+by the mirror symmetry, we have rx
+12(k0) ̸= 0, but
+ry
+12(k0) = 0. This means that the linear (or direct) opti-
+cal transition between the 1st and 2nd bands along ky is
+forbidden. Similarly we calculate the rb
+nm;a of the valley
+point k0 [see Eq. (S14) in SI], and we have,
+ry
+21;y(k0) =
+i
+ω21
+�
+B23B31
+� 1
+ω31
++
+1
+ω32
+�
+− 2E21
+�
+.
+(10)
+In the model, the value of ry
+21,y (and therefore Iyxy
+12 ) de-
+pends mainly on the virtual transitions, B23B31, which
+corresponding to the last term in Eq. 20. The first term
+in Eq. 20 vanishes, because B12=0. This is remarkable
+that the linear (direct) optical transition between the 1st-
+band and the 2nd-band in the y direction is forbidden,
+but the nonlinear transition may occur because both the
+1st-band and 2nd-band have strong coupling with the
+3rd-band, which leads to the giant shift-current effect.
+This effect is quite different from that of the two-band
+models for Weyl semimetals [17].
+The giant shift-current effects have even more profound
+origins. An alternative expression for the shift-current
+conductivity is written as [17],
+σyxy = −πe3
+ℏ2
+�
+k
+�
+n,m
+fnm
+�
+Ry
+mn;y − Rx
+nm;y
+�
+rx
+nmry
+mn
+δ (ωmn − ω) ,
+(11)
+where,
+Rb
+mn;a = i∂a ln rb
+mn + Aa
+mm − Aa
+nn,
+(12)
+is known as the shift vector, which characterizes the dis-
+placement of electrons in real space during the inter-band
+transition [1, 29, 30]. The shift vector is a gauge invariant
+quantity and can be viewed as a quantum geometric po-
+tential [31]. According to the perturbation theory, near
+k0, ry
+12(k) = f4 ky + f5 δkxky, where f4 and f5 are con-
+stants. In the model, Aa
+11(k0) = 0 and Aa
+22(k0) = 0 at k0,
+and both are small around k0. We can therefore neglect
+them in the following calculations. As k approaches k0
+along ky, i.e., δkx=0, we have,
+Ry
+12;y = i∂y ln (f4 ky) = i
+ky
+,
+(13)
+i.e., Ry
+12;y is purely imaginary and goes to infinity. There-
+fore, k0 is a singular point for the shift vector Ry
+12;y,
+which is a monopole in k-space. When ky is approaching
+zero, ry
+12 is also approaching zero as discussed in previ-
+ous sections, and Rx
+21;yrx
+21ry
+12 vanishes, but Ry
+12;yrx
+21ry
+12
+is still finite (actually very large) and purely real (see
+Fig. 3). The shift vectors also play important roles in
+second harmonic generation [17, 32, 33]. It is therefore
+expected that the SnTe monolayer would has non-trivial
+second harmonic responses. The divergent of the shift
+vector at the “optical zero” (i.e., rcv = 0) was discussed
+in Ref. [34]. However, the relation between the giant shift
+current and the divergent shift vector is not revealed.
+Very recently, nonlinear optical transitions have been
+related to the Riemannian geometry of the energy bands
+[17, 35]. We may define the quantum geometric tensor
+
+5
+between two bands m and n,
+Qmn
+ba = rb
+nmra
+mn ≡ gmn
+ba − i
+2F mn
+ba , a, b = x, y, z
+(14)
+where gmn
+ba
+is the band-resolved quantum metric, F mn
+ba
+is the band-resolved Berry curvature, and the two ge-
+ometric quantities are related to U(1) quantum metric
+and Berry curvature as gn
+ba = �
+m̸=n gmn
+ba
+and Ωn
+c =
+�
+m̸=n ϵcbaF mn
+ba /2 [36, 37].
+In our case, we consider the transition between the
+1st band and the 2nd band, and the quantum geometric
+tensor of the two bands is given by Q12
+xy = rx
+12ry
+21. We
+have Q12
+xy(k0) = 0 because ry
+21(k0) = 0. However, we
+show that the partial derivative of the imaginary part of
+Q12
+xy is related to Iyxy
+12 , i.e.,
+Im [Iyxy
+12 (k0)] = ∂y Im
+�
+Q12
+xy
+���
+k=k0 = −1
+2 ∂yF 12
+xy
+��
+k=k0 .
+(15)
+Figure 4(a) illustrates the distribution of Im[Q12
+xy] near k0
+and its derivative with respect to ky is shown in Fig. 4(b).
+Im[Q12
+xy] has a maximum (minimum) at δky=0.05 (δky=-
+0.05) and δkx=0, which is very similar to the Berry cur-
+vature distribution in Fig. 2a of Ref. [23]. Furthermore,
+Im[Q12
+xy] changes rapidly around δky=0, and as a con-
+sequence, Im [Iyxy
+12 (k0)] has a maximum at k0, which is
+consistent with that from direct calculations.
+We have shown that the giant shift-current and Glass
+coefficient are directly induced by the nontrivial geome-
+try of the energy band near the valley points. There is
+no reason that the diverging shift vector is unique to the
+SnTe monolayer. Experimentally, the giant Glass coeffi-
+cient is a good sign for the diverging shift-vector. How-
+ever, the phenomena are best observed when the singular
+points are at the band edge, where they are isolated. If
+the singular points are in the middle of the energy bands,
+the signal may be covered by the light absorption from
+other k points.
+CONCLUSIONS
+We find a huge shift current effect as well as an enor-
+mously large Glass coefficient in the ferroelectric SnTe
+monolayer.
+These unusual effects are induced by the
+non-trivial energy band geometry near the valley points,
+where the shift-vector diverges.
+This is another emi-
+nent example in which the geometry of the Bloch state
+plays a profound role in the fundamental properties of
+a solid. Whereas most previous examples focus on the
+ground state properties of the solids, this example shows
+the case of excitation in terms of nonlinear optical tran-
+sitions, which may have great potential applications in
+photoelectric devices.
+FIG. 4. The distributions of (a) Im
+�
+Q12
+xy
+�
+and (b) ∂y Im
+�
+Q12
+xy
+�
+around the valley point k0.
+METHODS
+The
+first-principles
+calculations
+are
+carried
+out
+with the Atomic orbital Based Ab-initio Computa-
+tion at UStc (ABACUS) code [38, 39] within the
+Perdew–Burke–Ernzerhof generalized gradient approxi-
+mation (GGA) for the exchange–correlation functional
+[40]. The ABACUS code is developed to perform large-
+scale density functional theory calculations based on nu-
+merical atomic orbitals (NAO) [38, 41]. The optimized
+norm-conserving Vanderbilt (ONCV) [42] fully relativis-
+tic pseudopotentials [43] from the PseudoDojo library[44]
+are used. The valence electrons for Sn, Te are 4d105s25p2,
+and 4d105s25p4, and the NAO bases for Sn and Te are
+2s2p2d1f and 2s2p2d1f, respectively [41].
+In the self-consistent and band structure calculations,
+the energy cut-off for the wave functions is set to 150
+Ry.
+The Brillouin zone is sampled using a Γ-centered
+16×16×1 k-point mesh. The structure is fully optimized
+until all forces are less than 1 meV/˚A.
+After the self-consistent calculations, the tight-binding
+Hamiltonian,
+Hµν(R) = ⟨0µ|H|Rν⟩,
+(16)
+
+(a)
+15
+20
+10
+10
+5
+0
+0
+-10
+-5
+-20
+0.05
+-10
+0.025
+0.05
+0
+0.025
+-15
+-0.025
+0
+-0.025
+S k.
+-0.05
+-0.05
+sk
+y
+x
+(b)
+700
+800
+600
+600
+500
+400
+400
+200
+300
+0
+200
+-200
+100
+0.05
+0
+0.025
+0.05
+0
+0.025
+-100
+-0.025
+0
+0.025
+-0.05
+S k.
+-0.05
+Sk
+y6
+the overlap matrices,
+Sµν(R) = ⟨0µ|Rν⟩,
+(17)
+and the dipole matrices (between the NAOs),
+rµν(R) = ⟨0µ|r|Rν⟩,
+(18)
+in
+the
+NAO
+bases
+are
+generated,
+where
+|Rν⟩
+=φν (r − τν − R) is the ν-th NAO in the R-th cell, and
+τν is the center of the ν-th NAO in the unit cell.
+The dipole matrix ra
+nm and its generalized derivative
+ra
+nm;b in the shift current Eq. (5) are calculated as fol-
+lows [3, 8, 25],
+ra
+nm = va
+nm
+iωnm
+(m ̸= n),
+(19)
+and
+ra
+nm;b =
+i
+ωnm
+�va
+nm∆b
+nm + vb
+nm∆a
+nm
+ωnm
+− wab
+nm
++
+�
+p̸=n,m
+�
+va
+npvb
+pm
+ωpm
+− vb
+npva
+pm
+ωnp
+��
+�
+(m ̸= n),
+(20)
+where,
+va
+nm = 1
+ℏ ⟨unk |∂aH(k)| umk⟩ ,
+∆a
+nm = ∂aωnm = va
+nn − va
+mm,
+wab
+nm = 1
+ℏ
+�
+unk
+��∂2
+abH(k)
+�� umk
+�
+.
+(21)
+The velocity matrix elements va
+nm are calculated by the
+ab initio tight-binding Hamiltonian Eqs. (16) - (18) [45,
+46].
+The band structures and the optical properties, such
+as the shift current are calculated using the tight-binding
+Hamiltonian implemented in the PY-ATB code [47].
+DATA AVAILABILITY
+All data generated and/or analysed during this study
+are included in this article.
+CODE AVAILABILITY
+The ABACUS code is an open source DFT code
+under the GPL 3.0 licence, which is available from
+http://abacus.ustc.edu.cn. The Py-ATB code, also un-
+der the GPL 3.0 licence, can be downloaded from
+https://github.com/jingan-181/pyatb.
+ACKNOWLEDGMENTS
+This work was funded by the Chinese National Science
+Foundation Grant Number 12134012. The numerical cal-
+culations were performed on the USTC HPC facilities.
+AUTHOR CONTRIBUTIONS
+L. He conducted the project.
+G. Jin developed the
+computer code and performed the calculations under the
+supervision of L. He. Both authors analyzed the results
+and wrote the manuscript.
+COMPETING INTERESTS
+The authors declare no competing interests.
+∗ Corresponding author: helx@ustc.edu.cn
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+
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+page_content=' 230026,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' People’s Republic of China  2Institute of Artificial Intelligence,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Hefei Comprehensive National Science Center,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Hefei,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Anhui,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 230026,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' People’s Republic of China  The bulk photovoltaic effect (BPVE) refers to the phenomenon of generating photocurrent or  photovoltage in homogeneous noncentrosymmetric materials under illumination,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' and the intrinsic  contribution to the BPVE is known as the shift current effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We calculate the shift current  conductivities of the ferroelectric SnTe monolayer using first-principles methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We find that the  monolayer SnTe has giant shift-current conductivity near the valley points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' More remarkably, the  linear optical absorption coefficient at this energy is very small, and therefore leads to an enormous  Glass coefficient that is four orders of magnitude larger than that of BaTiO3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The unusual shift-  current effects are further investigated using a three-band model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We find that the giant shift current  conductivities and Glass coefficient are induced by the nontrivial energy band geometries near the  valley points, where the shift-vector diverges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' This is a prominent example that the band geometry  can play essential roles in the fundamental properties of solids.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  INTRODUCTION  The study of BPVE has a long history [1–3], and re-  cently it has attracted great renewed interest because it  potentially allows the energy conversion efficiency to sur-  pass the Shockley–Queisser limit [4, 5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The shift-current  effects are believed to be the main intrinsic contribution  to the BPVE [3, 6], which can be used as an alternative to  the photocurrent generated by traditional semiconductor  p–n junctions [7, 8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' It has been demonstrated that the  photovoltage generated by shift-current effects can be far  above the band gap [9–12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The high priority of current studies in the field is to find  novel materials that have high shift-current conductivi-  ties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Cook et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' proposed design principles of the shift  current materials through an effective two-dimensional  model and successfully applied them to monochalco-  genide GeS [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' In addition to conventional ferroelectric  materials [13, 14], special attention has been given to  Weyl semimetals because of the unique topological na-  ture of band structures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Osterhoudt et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' discovered a  huge mid-infrared BPVE in the Weyl semimetal TaAs,  which is linked to the topological properties of the ma-  terial [15].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Type-II Weyl semimetal TaIrTe4 has been  found to have a huge optical response, and the shift cur-  rent is related to the divergent Berry curvature at the  Weyl nodes [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Ahn et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' theoretically studied the low-  frequency properties of BPVEs in topological semimet-  als, and revealed the relation between the shift current as  well as the injection current and the quantum geometry  of the material near the Weyl point [17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  In this work, we investigate the nonlinear optical prop-  erties of the two-dimensional ferroelectric material SnTe  monolayer [18] using first-principles methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We find  that it has giant shift current conductivities near the  valley points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  More remarkably, the linear optical ab-  sorption coefficient at this energy is very small, which  leads to an enormous Glass coefficient of four orders of  magnitude larger than that of bulk BaTiO3 [1, 5, 19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We develop a minimal three-band model to analyze the  mechanism of the giant shift-current effect in the SnTe  monolayer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We find that the giant shift-current effects  are induced by the nontrivial band structure geometry,  where the shift-vector diverges at the valley point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We  further show that the giant shift-current is related to the  derivatives of the imaginary part of the quantum geo-  metric tensor near the point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The mechanism is different  from the previous works on the Weyl semimetals [17],  and therefore opens a new play ground for the fascinat-  ing physical properties that are determined by the band  structure geometries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  RESULTS  Crystal structure  In 2016, Chang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' [18] discovered that the SnTe  monolayer has robust in-plane ferroelectricity with a  Curie temperature as high as 270 K, which is greatly  enhanced from its bulk value of 98 K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' As a member  of the Group IV monochalcogenide (MX, M = Ge, Sn,  Pb;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' X = S, Se, Te) family, the SnTe monolayer, which  has great potential in miniaturized ferroelectric devices,  has been extensively studied experimentally [20] and via  first-principles calculations [21–23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The structure of the  SnTe monolayer is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 1, which has a hinge-  like structure similar to that of phosphorene.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The SnTe  monolayer has a Pmn21 space group with mirror sym-  metry (Mxz) and glide mirror symmetry (G).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' It has an  in-plane ferroelectricity along the x-axis [20–23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The lack of inversion symmetry suggests that the SnTe  monolayer should have shift-current effects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We per-  form first-principles calculations to investigate the shift-  current effects in the SnTe monolayer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Details of the  calculations are presented in the METHODS section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='13391v1  [cond-mat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='mtrl-sci]  31 Jan 2023  2  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (a) Top view, (b) side view along the x direction and  (c) side view along the y direction of the crystal structure of  the SnTe monolayer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Sn and Te atoms are shown using blue  and red spheres, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The unit cell is indicated by  the dashed rectangle in (a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (d) The band gap between the  lowest conduction band and the highest valence band in the  Brillouin zone, where k0, ¯k0 k1 and ¯k1 are the valley points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Band structure and shift current conductivities  The band structures of SnTe monolayer with and with-  out spin-orbit coupling (SOC) are shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='S1 of the  Supplementary Information (SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' There are four valley  points of the band structure in the first Brillouin zone.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Two valley points, k0=(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='41, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0), k1=(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='41), in di-  rect coordinates, are on the Γ-X line and Γ-Y line re-  spectively, whereas the other two valley points are ob-  tained by the time inversion symmetry of the above two  k-points, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=', ¯k0 = −k0 and ¯k1 = −k1, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  1(d).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The introduction of SOC only slightly changes the  positions of the valley points (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' S1 in SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The break of inversion symmetry would lead to the  shift current in the SnTe monolayer, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=', a nonlinear dc  photocurrent under illumination [1–3],  Ja = 2σabc(0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' ω, −ω)Eb(ω)Ec(−ω),  (1)  where σabc(0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' ω, −ω) is the shift-current conductivity,  and a (b, c)=x, y, z are the crystal axes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Due to the  2D monolayer structure, we do not consider the current  in the z-direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Similarly, we do not consider the elec-  tric field applied in the z-direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Because of the mirror  symmetry Mxz of the SnTe monolayer, only σxxx, σxyy,  and σyxy=σyyx are nonzero (see the SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We investigate the shift-current conductivities by using  first-principles calculations [3, 24–26], and the numerical  results are consistent with the above symmetry analy-  sis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The 3D-like conductivities are obtained assuming  an active single-layer thickness of 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='12 ˚A[25, 27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Al-  though quantitatively, the results with and without SOC  are somehow different, but the inclusion of SOC does  not affect the main results and conclusions of the paper  (see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' S4 in SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Therefore, we only discuss the re-  sults without SOC here, and the analysis can be equally  applied to the results with SOC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Figure 2(a) depicts σyxy, which is the largest compo-  nent of the shift-current conductivities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' σyxy has three  distinct peaks at 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='24 eV, and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='18 eV, respec-  tively, in the energy interval 0∼4 eV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The highest peak  is at ℏω0=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV, with σyxy  3D =481.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='89 µA/V2, which is  significantly larger than the known high BPVE material  GeS of the order of 150 µA/V2 and 250 µA/V2 in state-  of-the-art Si-based solar cells [25, 27, 28].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  To experimentally explore this effect, we may apply  light with an electric field polarized along the [110] direc-  tion, and measure the shift current along the y direction,  which gives  jy = 2σyxyEx(ω)Ey(−ω).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (2)  In previous works [7, 8, 25], it has been suggested that  to have a large shift current, a large joint density of states  (JDOS) is necessary, which has been used as a design  principle in finding materials with a large shift current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Surprisingly, we find that the JDOS at ℏω0=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV is  extremely small as plotted in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  S2 in the SI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' As a  consequence, the absorption coefficients are expected to  be small at this photon energy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Indeed, the absorption  coefficient α[110] is also very small around ℏω0=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV,  as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 2(b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' What is more amazing is that  the absorption coefficient αyy=0 at this energy, strongly  against our intuition, given that σyxy is huge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The above results have important physical conse-  quences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We compute the Glass coefficient [1, 7, 9, 24]  gabc = α−1σabc,  (3)  and the result of gyxy is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 2(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' gyxy has  a sharp peak at ℏω0=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV, due to the giant σyxy  and small α[110].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The calculated Glass coefficient gyxy  of the SnTe monolayer at ℏω0=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV is 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='2 × 10−5  cm·V−1 [27], which is four orders of magnitude higher  than g31=3×10−9 cm·V−1 of the bulk (001)-oriented  BaTiO3 crystal [1, 5, 19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The Glass coefficient g plays  essential roles in the shift current related physical prop-  erties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' For example, the photovoltaic field generated by  the shift current [1, 5] can be estimated as,  Epv ≈  g  φ(µτ)pv  ℏω  e ,  (4)  where φ is the quantum yield, ℏω is the incident photon  energy and µ and τ are the mobility and lifetime of the  carriers responsible for photoconductivity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' A very large  g will lead to a very large photovoltaic field Epv, as in  this case, the “leaking” current due to photoconductivity  is much weaker than the shift current.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The photovoltaic  power conversion efficiency is also closely related to the  Glass coefficient [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (a)  (q)  Sn  Te  (c)  (d)  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='4  4  X  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='2  3  Ko  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0  Z  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='2  2  k1  X  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='4-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='2 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='4  kx3  0  1  2  3  4  0  200  400  yxy  3D  ( A/V2)  (a)  0  1  2  3  4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='5  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='5  [110] (105cm  1)  (b)  0  1  2  3  4  (eV)  0  2  4  gyxy (10  5 cm V  1)  (c)  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (a) Shift current conductivity σyxy  3D of the SnTe mono-  layer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' There are three peaks at 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='24, and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='18 eV, re-  spectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The highest peak is at 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (b) The absorp-  tion coefficient α[110] and (c) the Glass coefficient of the SnTe  monolayer, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The Glass coefficient has a sharp  peak at 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  DISCUSSION  Origin of the giant shift current in yxy direction  It is particularly interesting and important to explore  the underlaying mechanism of the giant shift-current con-  ductivity and Glass coefficient in the SnTe monolayer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The shift-current tensor is given by [3],  σabc(0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' ω, −ω) =πe3  ℏ2  �  dk  8π3  �  n,m  fnm Im  �  Iabc  mn  +Iacb  mn  �  δ (ωmn − ω) ,  (5)  where fnm=fn − fm and ℏωnm=Em − En are differences  between Fermi occupation factors and band energies, re-  spectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Iabc  mn = rb  mnrc  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a, where ra  nm is the inter-band  dipole matrix, and rb  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a is the generalized derivative of  the dipole matrix, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=',  ra  nm = (1 − δnm)Aa  nm,  (6)  ra  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='b = ∂bra  nm − i  �  Ab  nn − Ab  mm  �  ra  nm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (7)  Here, Aa  nm is the non-Abelian Berry connection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' More  detailed calculations of ra  nm and ra  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='b are described in  Methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Although ra  nm and rb  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a are gauge dependent,  their norm |ra  nm| and |rb  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a|, as well as Iabc  mn are gauge  invariant [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Note that ra  nm and rb  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a and Iabc  mn are all  k dependent, but here we drop the k index for simplicity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We calculate �  n,m fnm Im [Iyxy  mn + Iyyx  mn ] δ (ωmn − ω0) ,  for ℏω0=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='87 eV, in the first BZ [see Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' S3(a) of SI].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We find the contribution solely comes from the transition  between the highest valence band and the lowest conduc-  tion band, around the valley points k0 and ¯k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Because  only the valley points contribute to the optical transi-  tions at ℏω0, the corresponding JDOS and linear absorp-  tion coefficient is very small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Furthermore, as shown in  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' S3(b) of SI, Ivc = Im [Iyxy  vc  + Iyyx  vc ], where v and c,  are the highest valence band and the lowest conduction  band, has a sharp peak at k0, which leads to the giant  shift-current conductivity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Figure 3(a) depicts the norm of rx  vc and ry  vc along ky  passing through k0, which are shown in red and blue solid  lines respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We see |rx  vc| has a maximum at ky=0,  whereas |ry  vc|=0 at k0 due to the mirror symmetry Mxz.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  However, as seen from Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 3(a), |ry  vc| changes rapidly  along ky around k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' One may speculate that ry  vc may  have a large partial derivative (Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 7) along ky at the  valley point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Indeed, as shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 3(b), |ry  cv;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y| has a  peak at k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We plot Ivc in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 3(c).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Interestingly, we  find that Ivc ≈ |rx  vc||ry  vc;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y| around k0 (See SI).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Both rx  vc  and ry  cv;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y reach the maximum at k0, which lead to the  giant Ivc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Three-band model  To gain a deeper insight into the physics, we construct  a minimal three-band model around the valley point k0,  H(k) = H0+Aδkx+Bδky +Cδk2  x+Dδkxδky +Eδk2  y, (8)  up to the quadratic terms of δk , where δk=k−k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' More  specifically, δkx=kx − 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='41, δky=ky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We therefore do not  distinguish ky and δky below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' In the model, the 1st-band  is the highest valence band, whereas the 2nd-band and  3rd-band correspond to the lowest two conduction bands  in the DFT calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We fit the Hamiltonian matrix  H(k) and velocity matrix vmn(k) from DFT calculations  around k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The fitted parameters of the model are given  in the SI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We first (numerically) calculate |rx  12|, |ry  12;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y|, and I12  of the three-band model, and the results are com-  pared with those of DFT calculations in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 3(a),(b),  4  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0  2  4  6  |ra  vc| (Å)  (a)  DFT |rx  vc|  DFT |ry  vc|  Model |rx  vc|  Model |ry  vc|  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0  50  100  150  |ry  cv;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' y| (Å2)  (b)  DFT  Model  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  k-PATH (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='41, -0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='07) to (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='41, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='07)  0  500  1000  Ivc (Å3)  (c)  DFT  Model  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (a) The norm of dipole matrix rx  vc and ry  vc along ky,  where v and c are highest valence band and lowest conduction  band, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (b) The norm of the generalized derivative  of dipole matrix, ry  cv;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y, along ky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (d) The Ivc=Im [Iyxy  vc  + Iyyx  vc ]  along ky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The results obtained from DFT and model calcula-  tions are shown in solid and dashed lines, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  and (c), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The three-band model can semi-  quantitatively reproduce the results of DFT calculations,  and the discrepancies are due to neglecting other bands.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Around k0, the wave functions of the three-band model  can be solved analytically via a second order pertur-  bation theory, and therefore ra  nm and ra  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='b can also  be calculated analytically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Especially, at k0 we have  vx  nm(k0) = Anm and vy  nm(k0) = Bnm, therefore  rx  nm(k0) = Anm  iωnm  ,  ry  nm(k0) = Bnm  iωnm  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (9)  Because A12̸=0, and B12=0, which is actually imposed  by the mirror symmetry, we have rx  12(k0) ̸= 0, but  ry  12(k0) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' This means that the linear (or direct) opti-  cal transition between the 1st and 2nd bands along ky is  forbidden.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Similarly we calculate the rb  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a of the valley  point k0 [see Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (S14) in SI], and we have,  ry  21;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y(k0) =  i  ω21  �  B23B31  � 1  ω31  +  1  ω32  �  − 2E21  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (10)  In the model, the value of ry  21,y (and therefore Iyxy  12 ) de-  pends mainly on the virtual transitions, B23B31, which  corresponding to the last term in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The first term  in Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 20 vanishes, because B12=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' This is remarkable  that the linear (direct) optical transition between the 1st-  band and the 2nd-band in the y direction is forbidden,  but the nonlinear transition may occur because both the  1st-band and 2nd-band have strong coupling with the  3rd-band, which leads to the giant shift-current effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  This effect is quite different from that of the two-band  models for Weyl semimetals [17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The giant shift-current effects have even more profound  origins.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' An alternative expression for the shift-current  conductivity is written as [17],  σyxy = −πe3  ℏ2  �  k  �  n,m  fnm  �  Ry  mn;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y − Rx  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y  �  rx  nmry  mn  δ (ωmn − ω) ,  (11)  where,  Rb  mn;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='a = i∂a ln rb  mn + Aa  mm − Aa  nn,  (12)  is known as the shift vector, which characterizes the dis-  placement of electrons in real space during the inter-band  transition [1, 29, 30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The shift vector is a gauge invariant  quantity and can be viewed as a quantum geometric po-  tential [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' According to the perturbation theory, near  k0, ry  12(k) = f4 ky + f5 δkxky, where f4 and f5 are con-  stants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' In the model, Aa  11(k0) = 0 and Aa  22(k0) = 0 at k0,  and both are small around k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We can therefore neglect  them in the following calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' As k approaches k0  along ky, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=', δkx=0, we have,  Ry  12;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y = i∂y ln (f4 ky) = i  ky  ,  (13)  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=', Ry  12;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y is purely imaginary and goes to infinity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' There-  fore, k0 is a singular point for the shift vector Ry  12;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='y,  which is a monopole in k-space.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' When ky is approaching  zero, ry  12 is also approaching zero as discussed in previ-  ous sections, and Rx  21;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='yrx  21ry  12 vanishes, but Ry  12;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='yrx  21ry  12  is still finite (actually very large) and purely real (see  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The shift vectors also play important roles in  second harmonic generation [17, 32, 33].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' It is therefore  expected that the SnTe monolayer would has non-trivial  second harmonic responses.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The divergent of the shift  vector at the “optical zero” (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=', rcv = 0) was discussed  in Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' [34].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' However, the relation between the giant shift  current and the divergent shift vector is not revealed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Very recently, nonlinear optical transitions have been  related to the Riemannian geometry of the energy bands  [17, 35].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We may define the quantum geometric tensor  5  between two bands m and n,  Qmn  ba = rb  nmra  mn ≡ gmn  ba − i  2F mn  ba , a, b = x, y, z  (14)  where gmn  ba  is the band-resolved quantum metric, F mn  ba  is the band-resolved Berry curvature, and the two ge-  ometric quantities are related to U(1) quantum metric  and Berry curvature as gn  ba = �  m̸=n gmn  ba  and Ωn  c =  �  m̸=n ϵcbaF mn  ba /2 [36, 37].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  In our case, we consider the transition between the  1st band and the 2nd band, and the quantum geometric  tensor of the two bands is given by Q12  xy = rx  12ry  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' We  have Q12  xy(k0) = 0 because ry  21(k0) = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' However, we  show that the partial derivative of the imaginary part of  Q12  xy is related to Iyxy  12 , i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=',  Im [Iyxy  12 (k0)] = ∂y Im  �  Q12  xy  ���  k=k0 = −1  2 ∂yF 12  xy  ��  k=k0 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (15)  Figure 4(a) illustrates the distribution of Im[Q12  xy] near k0  and its derivative with respect to ky is shown in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 4(b).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  Im[Q12  xy] has a maximum (minimum) at δky=0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05 (δky=-  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05) and δkx=0, which is very similar to the Berry cur-  vature distribution in Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 2a of Ref.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' [23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Furthermore,  Im[Q12  xy] changes rapidly around δky=0, and as a con-  sequence, Im [Iyxy  12 (k0)] has a maximum at k0, which is  consistent with that from direct calculations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  We have shown that the giant shift-current and Glass  coefficient are directly induced by the nontrivial geome-  try of the energy band near the valley points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' There is  no reason that the diverging shift vector is unique to the  SnTe monolayer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Experimentally, the giant Glass coeffi-  cient is a good sign for the diverging shift-vector.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' How-  ever, the phenomena are best observed when the singular  points are at the band edge, where they are isolated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' If  the singular points are in the middle of the energy bands,  the signal may be covered by the light absorption from  other k points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  CONCLUSIONS  We find a huge shift current effect as well as an enor-  mously large Glass coefficient in the ferroelectric SnTe  monolayer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  These unusual effects are induced by the  non-trivial energy band geometry near the valley points,  where the shift-vector diverges.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  This is another emi-  nent example in which the geometry of the Bloch state  plays a profound role in the fundamental properties of  a solid.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Whereas most previous examples focus on the  ground state properties of the solids, this example shows  the case of excitation in terms of nonlinear optical tran-  sitions, which may have great potential applications in  photoelectric devices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  FIG.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The distributions of (a) Im  �  Q12  xy  �  and (b) ∂y Im  �  Q12  xy  �  around the valley point k0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  METHODS  The  first-principles  calculations  are  carried  out  with the Atomic orbital Based Ab-initio Computa-  tion at UStc (ABACUS) code [38, 39] within the  Perdew–Burke–Ernzerhof generalized gradient approxi-  mation (GGA) for the exchange–correlation functional  [40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The ABACUS code is developed to perform large-  scale density functional theory calculations based on nu-  merical atomic orbitals (NAO) [38, 41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The optimized  norm-conserving Vanderbilt (ONCV) [42] fully relativis-  tic pseudopotentials [43] from the PseudoDojo library[44]  are used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The valence electrons for Sn, Te are 4d105s25p2,  and 4d105s25p4, and the NAO bases for Sn and Te are  2s2p2d1f and 2s2p2d1f, respectively [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  In the self-consistent and band structure calculations,  the energy cut-off for the wave functions is set to 150  Ry.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The Brillouin zone is sampled using a Γ-centered  16×16×1 k-point mesh.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The structure is fully optimized  until all forces are less than 1 meV/˚A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  After the self-consistent calculations, the tight-binding  Hamiltonian,  Hµν(R) = ⟨0µ|H|Rν⟩,  (16)  (a)  15  20  10  10  5  0  0  10  5  20  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  10  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  15  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  S k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  sk  y  x  (b)  700  800  600  600  500  400  400  200  300  0  200  200  100  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  100  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  0  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='025  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  S k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='05  Sk  y6  the overlap matrices,  Sµν(R) = ⟨0µ|Rν⟩,  (17)  and the dipole matrices (between the NAOs),  rµν(R) = ⟨0µ|r|Rν⟩,  (18)  in  the  NAO  bases  are  generated,  where  |Rν⟩  =φν (r − τν − R) is the ν-th NAO in the R-th cell, and  τν is the center of the ν-th NAO in the unit cell.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The dipole matrix ra  nm and its generalized derivative  ra  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='b in the shift current Eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (5) are calculated as fol-  lows [3, 8, 25],  ra  nm = va  nm  iωnm  (m ̸= n),  (19)  and  ra  nm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='b =  i  ωnm  �va  nm∆b  nm + vb  nm∆a  nm  ωnm  − wab  nm  +  �  p̸=n,m  �  va  npvb  pm  ωpm  − vb  npva  pm  ωnp  ��  �  (m ̸= n),  (20)  where,  va  nm = 1  ℏ ⟨unk |∂aH(k)| umk⟩ ,  ∆a  nm = ∂aωnm = va  nn − va  mm,  wab  nm = 1  ℏ  �  unk  ��∂2  abH(k)  �� umk  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  (21)  The velocity matrix elements va  nm are calculated by the  ab initio tight-binding Hamiltonian Eqs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' (16) - (18) [45,  46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  The band structures and the optical properties, such  as the shift current are calculated using the tight-binding  Hamiltonian implemented in the PY-ATB code [47].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  DATA AVAILABILITY  All data generated and/or analysed during this study  are included in this article.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  CODE AVAILABILITY  The ABACUS code is an open source DFT code  under the GPL 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0 licence, which is available from  http://abacus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='ustc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='edu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='cn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The Py-ATB code, also un-  der the GPL 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='0 licence, can be downloaded from  https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='com/jingan-181/pyatb.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  ACKNOWLEDGMENTS  This work was funded by the Chinese National Science  Foundation Grant Number 12134012.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' The numerical cal-  culations were performed on the USTC HPC facilities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  AUTHOR CONTRIBUTIONS  L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' He conducted the project.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Jin developed the  computer code and performed the calculations under the  supervision of L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' He.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content=' Both authors analyzed the results  and wrote the manuscript.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  COMPETING INTERESTS  The authors declare no competing interests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
+page_content='  ∗ Corresponding author: helx@ustc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/qtFQT4oBgHgl3EQftTaK/content/2301.13391v1.pdf'}
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+Large Language Models Are Implicitly Topic Models:
+Explaining and Finding Good Demonstrations for In-Context Learning
+Xinyi Wang 1 Wanrong Zhu 1 William Yang Wang 1
+Abstract
+In recent years, pre-trained large language mod-
+els have demonstrated remarkable efficiency in
+achieving an inference-time few-shot learning ca-
+pability known as in-context learning. However,
+existing literature has highlighted the sensitiv-
+ity of this capability to the selection of few-shot
+demonstrations. The underlying mechanisms by
+which this capability arises from regular language
+model pretraining objectives remain poorly under-
+stood. In this study, we aim to examine the in-
+context learning phenomenon through a Bayesian
+lens, viewing large language models as topic mod-
+els that implicitly infer task-related information
+from demonstrations. On this premise, we pro-
+pose an algorithm for selecting optimal demon-
+strations from a set of annotated data and demon-
+strate a significant 12.5% improvement relative
+to the random selection baseline, averaged over
+eight GPT2 and GPT3 models on eight different
+real-world text classification datasets. Our em-
+pirical findings support our hypothesis that large
+language models implicitly infer a latent concept
+variable.1
+1. Introduction
+Recently, transformer-based (Vaswani et al., 2017) pre-
+trained LLMs (LLMs) have demonstrated significant ad-
+vancements in a variety of natural language processing
+(NLP) tasks. As the size of these LLMs increases, the
+ability to perform in-context learning (Brown et al., 2020)
+emerges, allowing models to achieve state-of-the-art or near
+state-of-the-art performance by conditioning on a task de-
+scription and a small number of demonstration examples
+at inference time, without any need for updating model pa-
+1Department of Computer Science, University of Cali-
+fornia, Santa Barbara.
+Correspondence to:
+Xinyi Wang
+<xinyi wang@ucsb.edu>.
+Preprint.
+1Code:
+https://github.com/WANGXinyiLinda/
+concept-based-demonstration-selection.
+rameters (Brown et al., 2020). Below is an example input
+sequence for semantic analysis with in-context learning:
+Great movie.
+Positive.
+The worst movie ever.
+Negative.
+Can’t wait to see the second movie!
+The first two lines are two demonstrations, and the third line
+is a test input. We expect an LLM to output the correct label
+Positive as a continuation.
+In-context learning has been demonstrated to be an effective
+technique for a wide range of natural language processing
+tasks. However, it has been shown to be sensitive to the
+choice, format, and even the order of the demonstrations
+used (Perez et al., 2021; Lu et al., 2022). This can make it
+challenging to achieve optimal performance without signifi-
+cant human effort invested in adjusting the format and selec-
+tion of demonstration examples. Heuristic solutions, such
+as selecting demonstrations based on the similarity between
+the demonstrations and test input (Liu et al., 2022; Su et al.,
+2022) have been proposed, but a comprehensive understand-
+ing of why certain demonstrations are effective while others
+are not remains elusive. Additionally, the mechanisms by
+which LLMs acquire the ability to perform in-context learn-
+ing through regular language model pre-training are not
+fully understood. Recent works on understanding in-context
+learning provide valuable insights and theoretical results
+(Xie et al., 2022; Chan et al., 2022; Aky¨urek et al., 2022;
+von Oswald et al., 2022). However, they are limited in scope,
+focusing on synthetic experiments to validate their hypothe-
+ses, while it remains unclear if these results generalize to
+LLMs pre-trained on real-world text data.
+In this paper, we aim to develop a more systematic and
+principled approach to optimizing the in-context learning
+prompt, drawing on an in-depth understanding of the un-
+derlying mechanisms of LLMs. Specifically, we focus on
+the choice of the few-shot demonstrations, while leaving
+out the use of task description and keeping the format of
+these demonstrations minimal. In this paper, we present
+empirical evidence demonstrating that when performing in-
+context learning, real-world LLMs such as GPT-2 (Radford
+et al., 2019) and GPT-3 (Brown et al., 2020) implicitly infer
+a concept variable of the underlying task from the given
+arXiv:2301.11916v1  [cs.CL]  27 Jan 2023
+
+Large Language Models Are Implicitly Topic Models
+demonstrations. This suggests that LLMs function in a sim-
+ilar manner to topic models, but with the distinction that the
+concept variable is learned implicitly. A topic model mod-
+els the text data distribution by assuming the presence of a
+latent variable, known as the topic variable, which governs
+the data generation process:
+P(w1:T ) =
+�
+Θ
+P(w1:T |θ)P(θ)dθ
+Where θ ∈ Θ represents a potentially high dimensional
+topic/concept variable, Θ is the space of the topic/concept
+variable, and w1:T refers to the token sequence of a data
+example, such as a sentence or document. A well-known
+example of a topic model is Latent Dirichlet Allocation
+(LDA) (Blei et al., 2003), which further assumes that each
+token in the example is mutually independent of one another
+given the topic variable. i.e. P(w1:T |θ) = �T
+i=1 P(wi|θ).
+On the other hand, LLMs model text data according to the
+general probabilistic decomposition:
+P(w1:T ) =
+T
+�
+i=1
+P(wi|wi−1, ..., w1)
+In this study, we focus specifically on generative LLMs
+that have been pre-trained with a language model objective.
+While in practice, LLMs generate new tokens based on
+all previous tokens, we investigate whether a simplified
+assumption similar to that of topic models can be made for
+LLMs, which would take the form of:
+PM(wt+1:T |w1:t) =
+�
+Θ
+PM(wt+1:T |θ)PM(θ|w1:t)dθ
+In this scenario, the generated tokens are assumed to be
+conditionally independent of previous tokens, given the
+topic/concept variable that acts like an approximate suffi-
+cient statistic for the posterior information related to the
+prompt w1:t. For in-context learning, this concept variable
+would include the format and meaning of the task inferred
+from the demonstrations.
+By conditioning on the appropriate concept variable, LLMs
+would generate the correct continuation with P(wt+1:T |θ).
+As LLMs do not explicitly learn a concept variable like
+LDA-style topic models (Blei et al., 2003), we can instead
+utilize this formulation under an Empirical Bayesian for-
+mulation to extract the concept variable for use. Drawing
+inspiration from Lester et al. (2021), we introduce new con-
+cept tokens to the vocabulary as prefixes and fine-tune only
+the embedding of these new tokens. By doing so, we can se-
+lect demonstrations that are most likely to infer the concept
+tokens of the task according to the LLM.
+Our findings indicate that the implicit-topic-model assump-
+tion is effective for in-context learning when the direction
+of inference is consistent with the causal direction of the
+generation process. To validate this empirically, we selected
+demonstrations (w1:t in the equations) that are most likely to
+infer or represent the desired latent concept variable (those
+with the highest posterior probability P(θ|wt+1:T )) and
+observed a significant improvement in performance when
+using these demonstrations for in-context learning.
+We observe that demonstrations selected based on one large
+language model (GPT2-large) can be transferred to other
+models (different size GPT2s and GPT3s) that have been
+trained on the same pre-training objective. This behavior
+of LLMs is likely a result of similar pre-training data dis-
+tributions. This finding is consistent with the discovery of
+Xie et al. (2022) that a pre-training distribution based on
+a Hidden Markov Model with latent concept variables can
+lead to the emergence of in-context learning.
+In this paper, we make the following contributions:
+• We provide a Bayesian explanation for how LLMs
+(LLMs) perform in-context learning by formulating
+them as implicit topic models;
+• We propose a cost-effective and efficient algorithm for
+selecting suitable demonstrations that can be general-
+ized to different LLMs;
+• Our explanation is supported by a comprehensive set
+of empirical experiments on GPT2s and GPT3s with
+various natural language processing datasets.
+2. Preliminaries
+In the context of in-context learning, the prompt w1:t is
+composed of several demonstrations and a test input. The
+generated tokens wt+1:T represent the prediction for the test
+input. Our settings, notations, and theoretical analysis of
+the problem will be discussed in further detail below.
+2.1. Notations and Problem Setting
+Suppose the objective of our task is to predict a discrete
+target variable Y ∈ Y, given a token sequence X ∈ X,
+where X is the space of all possible token sequences. θ ∈ Θ
+is the latent concept variable, where Θ is the space of the
+concept variable. Note that, unlike the traditional topic
+model, θ is not assumed to be discrete, and Θ is not assumed
+to be finite. To define the data generation process, we posit
+the existence of an underlying causal relation between X, Y ,
+and θ. We examine two potential directions of this causal
+relation, namely X � Y � θ and Y � X � θ, which can
+be represented mathematically as the following structural
+equations:
+Y = f(X, θ, ϵ)
+X = g(Y, θ, ϵ)
+
+Large Language Models Are Implicitly Topic Models
+Here ϵ ∈ E is an independent noise variable, f : X × Θ ×
+E → Y and g : Y × Θ × E → X are two deterministic
+functions. Furthermore, we denote the joint data distribution
+by X, Y, θ ∼ P, and assume that Y is sampled from a uni-
+form distribution over Y. The distinction between these two
+directions is crucial, as it allows us to utilize the direction
+in which the child variable (Y or X) is independent of the
+other variables, given its parents.
+We hypothesize that the causal direction is dependent on
+the nature of the task at hand. For instance, in the task of
+predicting the sentiment (Y ) of a movie review (X), it is
+reasonable to assume that the opinion about the movie is
+formed prior to the writing of the review, thus making Y
+the cause of X, along with the task concept of “writing
+a passage to express one’s opinion about the movie” (θ).
+Conversely, for the task of identifying grammatical errors
+(Y ) in a sentence (X), it is plausible that the sentence is not
+intentionally written with errors, leading to the conclusion
+that X is the cause of Y , along with the task concept of
+“identifying grammatical errors in a sentence” (θ). In the
+rest of the paper, we will focus on the discussion of the
+X � Y � θ direction, and leave a detailed discussion of
+the other direction to the Appendix.
+In order to perform in-context learning with an LLM
+(generically denoted by model label M),
+we con-
+dition on a fixed set of k demonstration examples
+(Xd
+1, Y d
+1 ), (Xd
+2, Y d
+2 ), ..., (Xd
+k, Y d
+k ) for a task d ∈ T , where
+T is the space of all possible tasks, and Xd
+i ∈ X, Y d
+i ∈ Y
+for all i ∈ [1, k]. In this approach, we do not include a task
+description in the prompt, with the aim of focusing on the
+examination of the demonstrations.
+The data generation process of a task d can be written as:
+Y d
+i = f(Xd
+i , θd, ϵ)
+Here θd ∈ Θ is the value of the concept variable corre-
+sponding to task d. To naturally project Y into the token
+space X, define injective mappings τ d : Y → X, which are
+typically defined by human understanding of the task d. e.g.
+for sentiment analysis, τ d map positive class to the token
+“positive” and negative class to the token “negative”. Addi-
+tionally, a delimiter token wd is defined, typically an empty
+space or a new line token, to separate the demonstrations
+when they are concatenated together. We denote the LLM
+output probability of X, Y , and θ, with the aforementioned
+preprocessing applied, by P d
+M:
+PM(τ d(Y )|Xd
+1, τ d(Y d
+1 ), wd, ..., Xd
+k, τ d(Y d
+k ), wd, X)
+= P d
+M(Y |Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)
+2.2. Problem Analysis and Modling
+We consider the scenario in which a small set of observed
+data, denoted as Dd, is available, allowing for the selection
+of the k most suitable demonstrations from it. Then, for any
+incoming test example X, we have:
+P d
+M(Y |Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)
+=
+�
+Θ
+P d
+M(Y |θ, X)P d
+M(θ|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)dθ (1)
+Here, we assume the sampling of the test example is in-
+dependent of the sampling of the demonstrations, so Y is
+independent of the demonstrations given θ and X. We also
+assume that the pre-trained data distribution P d
+M is a suitable
+approximation of the assumed data distribution P:
+Assumption 2.1. Assume that PM(X) = P(X), and
+P d
+M(Y |θ, X) ∝ P(Y |θ, X) for X � Y � θ.
+It is important to note that while it is assumed that the
+LLM perfectly learns the general text distribution, this is
+not entirely accurate in practice. According to LeBrun et al.
+(2022), LLMs systematically underestimate rare text se-
+quences, which constitute a significant portion of the long-
+tail distribution of language. Although this assumption is
+adequate to achieve favorable empirical results, it is ex-
+pected that more accurate language models will, in theory,
+lead to improved outcomes. With this assumption in mind,
+the following is established:
+Proposition 2.2. If task d follows the X � Y � θ direction,
+then arg maxy∈Y P d
+M(Y = y|θd, X) is the Bayes optimal
+classifier.
+In this case, only when P d
+M(θ|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X) com-
+pletely concentrate on θd, can the in-context learning clas-
+sifier become the Bayes optimal classifier (Devroye et al.,
+1996):
+Theorem 2.3. If task d follows the X � Y � θ direction,
+then the in-context learning classifier
+arg max
+y∈Y
+P d
+M(Y = y|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)
+always has a higher or equal probability of misclassifica-
+tion to the Bayes optimal classifier arg maxy∈Y P d
+M(Y =
+y|θd, X). Equality only takes when
+∀x ∈ X, P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X = x) = 1.
+A similar argument can be made for the Y � X � θ
+direction. Here, Equation (1) would become:
+P d
+M(X|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y )
+=
+�
+Θ
+P d
+M(X|θ, Y )P d
+M(θ|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y )dθ (2)
+Note that Equation (1) and Equation (2) are very similar
+to the direct and channel method introduced in Min et al.
+(2022a). The detailed argument of the Y � X � θ direction
+can be found in Appendix A.2.
+
+Large Language Models Are Implicitly Topic Models
+Figure 1. An overview of our proposed two-phased algorithm. Demonstration selection and latent concept learning share the same LLM
+as demonstration selection needs to reuse the learned concept tokens, while at the in-context learning time, any other generative LLM
+can be used. Note that here we only illustrate the X � Y � θ direction. The Y � X � θ direction can be illustrated similarly by
+exchanging X and Y in the above figure.
+3. Method
+In this section, we will first introduce how to estimate the
+concept variable with an LLM and a collection of tasks
+with training data. Then, we will discuss how to select an
+optimal set of demonstrations for a task such that the in-
+context learning classifier can become closer to the Bayes
+optimal classifier, by using the learned concept variable.
+Figure 1 is an overall illustration of our proposed method.
+3.1. Latent Concept Learning
+To reveal the underlying latent concept variable θ within the
+LLM M, we can utilize Proposition 2.2. Building upon the
+methodology proposed by Lester et al. (2021), for each spe-
+cific task d, c new concept tokens (denoted as ˆθd) are added
+to the original vocabulary of LLM M to represent the corre-
+sponding task concept θd. Subsequently, the embedding of
+these new tokens Enew(ˆθd) is fine-tuned while freezing the
+remaining parameters of LLM M. The variable c is treated
+as a hyperparameter. In practice, in order to condition on
+θd, the corresponding c concept tokens are appended to the
+input X (or Y ) as demonstrated in the example provided
+below, where c = 2:
+<sentiment token 1><sentiment token 2>
+Can’t wait to see the second movie!
+By giving the above input tokens, we ask the LLM to
+predict the correct label Positive for us.
+Note that
+<sentiment token 1> here is just a label assigned to
+the newly added concept token. It can be anything as long
+as it does not overlap with the original vocabulary of LLM.
+As reported in Lester et al. (2021), the larger the c is, the
+better the classifier arg maxy∈Y P d
+M(Y = y|ˆθd, X) would
+be. In practice, usually a small c (i.e., 10 to 50) would be
+enough to obtain good performance.
+The fine-tuning objective would then be minimizing
+L(ˆθd) = EX,Y [ℓ(X, Y ; ˆθd)], where
+ℓ(X, Y ; ˆθd) =
+�
+− log P d
+M(Y |ˆθd, X)
+if X � Y � θ
+− log P d
+M(X|ˆθd, Y )
+if Y � X � θ.
+Theoretically, if we can minimize the above loss function,
+a Bayes optimal classifier can be obtained, and the concept
+tokens would be a reasonable delegate of the real latent
+concept variable:
+Proposition
+3.1.
+When
+L(ˆθd)
+is
+minimized,
+P d
+M(Y |ˆθd, X) = P(Y |θd, X) for X � Y
+� θ. If θ
+is identifiable, then ˆθd = θd.
+We denote the LLM M with fine-tuned concept tokens by
+M ′. Since we add the concept tokens into the regular token
+vocabulary, the raw LLM output of the probability of the
+concept tokens PM ′(θ) would be in the token sequence
+space X instead of the concept space Θ. Since computing all
+possible concept values in the concept space Θ is infeasible,
+we propose to approximate the concept space Θ by sampling
+a diverse subset of tasks S from the whole task space T .
+Then the estimated concept probability of θd would be:
+P d
+M(θd) ≈ ˆP d
+M ′(ˆθd) =
+P d
+M ′(ˆθd)
+�
+t∈S P t
+M ′(ˆθt)
+And the fine-tuning loss becomes �
+d∈S L(θd). Here, we
+assume we have a reasonable-sized dataset D for each task
+d, and we would be able to estimate the expectation EX,Y
+by averaging over the training dataset. We summarize the
+proposed algorithm in Algorithm 1.
+Note that the embedding matrix of a generative LLM is
+shared on both the input and output sides. So while we
+only see the concept tokens on the input side at the training
+time, they can be viewed as regular word tokens that can be
+generated on the output side.
+
+Test Y
+LLM
+LLM
+LLM
+XkYk
+Test X
+Dataset
+XY
+θXY
+YθXLarge Language Models Are Implicitly Topic Models
+Algorithm 1 Latent concept learning
+Input: dataset D associated with a set of tasks S. LLM
+M, number of concept tokens per task c, learning rate α,
+and number of training steps L.
+Output: LLM M ′ with fine-tuned concept tokens.
+Add c|S| new tokens to the vocabulary;
+Randomly initialize their embeddings Enew;
+Freeze all parameters in M except Enew;
+for i = 1 to L do
+Sample a random batch B in D;
+Initialize gradient g ← 0;
+for each data point (x, y, d) in B do
+g = g + ∂ℓ(X,Y ;ˆθd)
+∂Enew
+;
+end for
+Enew = Enew − αg;
+end for
+3.2. Demonstration Selection
+According to Theorem 2.3, for a task d, to get a higher
+accuracy at in-context learning time, we need to se-
+lect demonstrations Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k
+that maximize
+P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X) for all X ∈ X. Then our
+goal then becomes selecting demonstrations that can best
+infer the task concept for all test inputs:
+arg max
+Xd
+1 ,Y d
+1 ,...,Xd
+k,Y d
+k
+EX[P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)]
+As test examples are sampled independent of the demonstra-
+tions, and PM(X) = P(X) according to Assumption 2.1,
+we have
+EX[P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)]
+=
+�
+X∈X
+P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)P(X)
+=P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k )
+Suppose each demonstration is also sampled independently.
+Then we have:
+P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k ) =
+�k
+i=1 P d
+M(θd|Xd
+i , Y d
+i )
+P d
+M(θd)k−1
+We assume that θ has a uniform prior.
+Then our goal
+becomes finding the top k demonstrations that maximize
+ˆP d
+M ′(ˆθd|Xd
+i , Y d
+i ).
+Note that, here, the independence between demonstra-
+tions is a simplified assumption to make the search space
+of (Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k ) smaller. In practice, selected
+demonstrations are likely correlated as some sets of demon-
+strations may work well together but not necessarily work
+well by themselves. However, it would be too expensive
+to search the O(|Dd|k) combinations over the candidate
+Algorithm 2 Demonstration selection
+Input: dataset Dd for a task d. LLM with fine-tuned
+concept tokens M ′. The number of demonstrations k.
+Output: A set of ordered demonstrations.
+for each (Xd, Y d) in Dd do
+Compute ˆP d
+M(ˆθd|Xd, Y d);
+end for
+Select top k examples with the largest ˆP d
+M(θd|Xd, Y d),
+denoted as (Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k );
+for each permutation π do
+Compute ˆP d
+M(ˆθd|π((Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k )));
+end for
+Select
+the
+permutation
+π
+with
+the
+largest
+ˆP d
+M(ˆθd|π((Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k ))).
+set Dd. We would like to leave this as a future research
+direction.
+Also, as we are using an LLM to approximate the data dis-
+tribution, the order of the demonstrations matters. We then
+choose the order according to the posterior of the concept
+tokens:
+arg max
+π∈Π
+ˆP d
+M(θd|π((Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k )))
+(3)
+Where π((Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k )) is a permutation of
+(Xd
+1, Y d
+1 ), ..., (Xd
+k, Y d
+k ). Π is the set of all possible permuta-
+tions of the k demonstrations. We summarize the proposed
+algorithm in Algorithm 2.
+Then we can use the selected demonstrations for in-context
+learning. In practice, we test the performance of the selected
+demonstrations with a held-out test set.
+4. Experiments
+Datasets. We conduct experiments on eight datasets from
+five different types of NLP classification tasks: sentiment
+analysis, linguistic analysis, topic classification, emotion
+classification, and hate speech detection. For sentiment anal-
+ysis, we choose the Stanford Sentiment Treebank (SST2)
+dataset (Socher et al., 2013) from the GLUE benchmark
+(Wang et al., 2018) and the financial phrase bank (FPB)
+dataset (Malo et al., 2014). SST2 is constructed based on
+movie reviews labeled “positive” or “negative”, and FPB is
+based on financial news labeled “positive”, “negative”, or
+“neutral”. For linguistic analysis, we choose the Corpus of
+Linguistic Acceptability (COLA) dataset (Warstadt et al.,
+2018) from the GLUE benchmark, based on sentences col-
+lected from linguistic books, labeled with “acceptable” or
+“unacceptable”. For topic classification, we choose the DB-
+pedia ontology classification dataset (Zhang et al., 2015),
+based on DBpedia 2014 (Lehmann et al., 2015), labeled
+with 14 different ontology classes. For emotion classifica-
+
+Large Language Models Are Implicitly Topic Models
+Figure 2. Accuracy of 4-shot in-context learning using demonstrations selected by our method and other baselines, averaged over eight
+datasets. Our demonstrations are selected using GPT2-large, and the same set of demonstrations is then applied to all other LLMs.
+Figure 3. Accuracy of randomly selected demonstrations averaged
+over seven different LLMs except for GPT3-davinci, using the
+adopted causal direction and the anti-causal direction.
+tion, we choose the dataset from Chatterjee et al. (2019) and
+Saravia et al. (2018), both of which are collected from Twit-
+ter. Chatterjee et al. (2019) (EmoC) predict emotion given a
+three-turn contextual dialogue, while Saravia et al. (2018)
+predict emotion given a Twitter message with clear emotion.
+For hate speech detection, we choose the online hate speech
+detection dataset (ETHOS) (Mollas et al., 2020), collected
+from online social media platforms. Here we detect two
+types of hate speech: sexual orientation (ETHOS-SO) and
+religion (ETHOS-R). While in Section 2, we assume that
+all tasks share the same label space Y, here we relax such
+assumption and allow a different number of labels for dif-
+ferent tasks. We use minimal formatting to process each
+example. A detailed description of the datasets and our data
+processing procedure can be found in Appendix B.
+Experiment settings. We adopt the X → Y ← θ causal di-
+rection for the linguistic analysis and hate speech detection
+type of tasks, as we usually do not intentionally use a lin-
+guistic property when writing a sentence and the hate speech
+is often not generated with a well-classified intention. On
+the other hand, we adopt the Y → X ← θ causal direction
+for the sentiment analysis, topic classification, and emotion
+classification tasks, as we usually intend to write a piece of
+text with some sentiment, or topic, or emotion. From an
+empirical perspective, we choose the direction that can give
+a higher accuracy when using random demonstrations, as
+shown in Figure 3.
+Without specification, we use k = 4 number of demonstra-
+tions and c = 10 number of concept tokens per dataset for
+our experiments, as the context length of GPT2 is 1024, and
+a larger number of demonstrations may not be able to fit into
+it. We use GPT2-large to learn the concept tokens and then
+compute the probability of each candidate demonstration
+example. We select our demonstrations from a randomly
+selected 100 example subset of the train set as the candidate
+set Dd. For our method, we use the same set of demon-
+strations selected by GPT2-large, for all other GPTs. We
+test the performance of the selected demonstrations using
+at most 1000 examples randomly sampled from the test set.
+Each experiment is repeated for five runs with different ran-
+dom seeds (the randomness comes from the sampling of the
+candidate set and the sampling of the test set). We adopt a
+large portion of the code from Min et al. (2022b), which is
+based on Huggingface (Wolf et al., 2019).
+Baselines. We consider the following baselines:
+• Uniform: for each test example, we uniformly select
+k demonstrations from the candidate set D.
+• Similar: According to Liu et al. (2022), demonstra-
+tions semantically similar to the test example would
+help. Following their method, we use a pre-trained
+sentence Transformer (Reimers & Gurevych, 2019) to
+calculate the cosine similarity between the demonstra-
+tions and test examples. For each test example, we
+choose the top k similar demonstrations from D.
+Main results.2 Figure 2 shows our main in-context learn-
+ing results averaged over all eight datasets, using the bare
+language model pre-trained GPT2s and GPT3s, without any
+instruction fine-tuning (Ouyang et al., 2022) or Reinforce-
+ment Learning from Human Feedback (RLHF) (Stiennon
+et al., 2020). Our method significantly outperforms base-
+lines on eight different LLMs. The demonstrations selected
+by our method are exclusively based on GPT2-large, while
+the same set of demonstrations can be generalized to all
+other LLMs. We hypothesize that this is because of the
+similar pre-training data distribution they have learned. To
+verify this hypothesis, we also test the performance of our
+2The complete results with standard deviations in this section
+can be found in Appendix B.
+
+Uniform
+ Similar
+Ours
+69.2
+66.9
+66.8
+66.6
+64.8
+65.1
+64.2
+62.6
+62.4
+62.3
+62.4 63.7
+61.2
+61.3
+60.3
+59.7
+60
+57.4
+57.7
+56.8
+56.2
+56.7
+56.8
+53.7
+GPT2
+GPT2-medium
+GPT2-large
+GPT2-xl
+GPT3-ada
+GPT3-babbage
+GPT3-curie
+GPT3-davinci
+(124M)
+(355M)
+(774M)
+(1.5B)
+(350M)
+(1.3B)
+(6.7B)
+(175B)CausalAnti-causal
+76.3
+73.6
+70
+60.8
+56.7 53
+57.7
+53.4 50.8
+54.1
+55.6
+38.8 37.4
+31.5
+26.6
+14.8
+SST2
+FPB
+COLA
+Dbpedia
+Emoc
+Emos
+ETHOS-SO ETHOS-RLarge Language Models Are Implicitly Topic Models
+Figure 4. Accuracy improvement of our proposed method versus
+randomly selected demonstrations, with instruction fine-tuned
+GPT3s, averaged over all eight datasets.
+Figure 5. Accuracy of in-context learning using our method versus
+the theoretical maximum accuracy obtained by using the learned
+concept tokens as prefixes. Numbers are obtained with GPT2-
+large.
+selected demonstrations on instruction fine-tuned GPT3s.
+As shown in Figure 4, our method’s improvement over ran-
+dom selection is significantly smaller when using instruction
+fine-tuned GPT3s.
+Ours versus optimal performance. As stated in Theo-
+rem 2.3, the optimal performance of an in-context learn-
+ing classifier should be the Bayesian optimal classifier
+arg maxy∈Y P d
+M(Y = y|θd, X). We compare the accuracy
+of in-context learning using our method, and the accuracy of
+using the learned concept tokens as prefixes, which approx-
+imate the Bayes optimal classifier. As shown in Figure 5,
+our method comes close to the optimal accuracy on some
+datasets while never becoming better, which empirically
+verifies the conclusion in Theorem 2.3. This indicates that
+there are two ways to improve our method: the first is to
+improve the performance of the optimal classifier, by intro-
+ducing a better latent concept learning algorithm. The other
+way is to reduce the performance gap between our method
+and the optimal classifier, by improving the demonstration
+selection algorithm.
+Effect of using ground truth labels. According to Min
+et al. (2022c), the ground truth label is not necessary for
+demonstrations to have a good in-context learning perfor-
+mance, which we found is not entirely true for all the
+tasks. We compare our method with the randomly selected
+demonstration baseline under three scenarios: (a) Original:
+demonstrations with the correct labels; (b) Random words:
+using a random label projection map τ d instead of a mean-
+ingful one. i.e., map each label to a fixed random word. In
+this case, the mapping from the input tokens X to the labels
+Y is still preserved; (c) Random labels: assign a random
+Figure 6. In-context learning accuracy of our method versus ran-
+dom selection baseline, with (a) ground truth labels (original), (b)
+random label mapping (random words), or random label assign-
+ments (random label), averaged over all eight datasets. Numbers
+are obtained with GPT2-large.
+Figure 7. In-context learning accuracy of our method versus ran-
+dom selection baseline, with different k, averaged over all eight
+datasets. Numbers are obtained with GPT3-ada.
+label to each demonstration, with the original label projec-
+tion map τ d. As shown in Figure 6, by using a random label
+projection map or randomly assigning the labels, the per-
+formance of the randomly selected demonstration baseline
+drops considerably. And randomize the label assignment
+gives a larger performance drop than only using a random la-
+bel projection map, which shows that the mapping between
+X and Y in the demonstrations matters. This indicates that
+in-context learning infers the mapping between X and Y
+from the demonstrations instead of merely invoking some
+learned function stored in the LLM parameters based on the
+appearance of X and Y . We also show that the demonstra-
+tions selected by our method represent the X − Y mapping
+better, as under the Random words condition, our method
+performs better than the random selection baseline, while
+our method does not improve the random selection baseline
+under the Random labels condition.
+k ablation study. While we use k = 4 demonstrations for
+all the experiments above, we also test the effectiveness
+of our method using different k. As shown in Figure 7,
+our method significantly outperforms the random selection
+baseline with k = 4, 8, and 16. Note that here we use
+GPT3-ada instead of GPT2s, because the context length of
+GPT2s is 1024, which could not fit in large ks. Also, we do
+not reorder the selected demonstrations according to Equa-
+tion (3), as we need to use GPT2-large to the reordering, and
+it cannot fit in all the demonstrations. Instead, we order the
+selected demonstrations from the largest ˆP d
+M(θd|Xd, Y d)
+to the smallest.
+Effect of demonstrations’ order. In Figure 8, we show that
+the demonstrations selected by our method are insensitive
+
+ILM
+instruct
+9.2
+7.4
+6.9
+6.3
+5.7
+3.2
+GPT3-ada (350M)
+GPT3-babbage (1.3B)
+GPT3-curie (6.7B)Optimal■Ours
+90.3 86.2
+92.6
+86.2 82.5
+86.1
+r
+78.2 76.6
+75
+69.1
+60.4
+56.5
+57.3
+53.8
+48.4
+38.6
+SST2
+FPB
+COLA
+Dbpedia
+EmoC
+Emos
+ETHOS-SO ETHOS-RUniform
+■Ours
+64.8
+57.4
+50.5
+47.5
+35.9
+35.3
+Original
+Random words
+Random labelsUniform
+Ours
+63.4
+63
+62.4
+58.8
+57.4
+56.8
+k=4
+k=8
+k=16Large Language Models Are Implicitly Topic Models
+Figure 8. In-context learning accuracy of our method versus ran-
+dom selection baseline, with and without reordering. The red error
+bars represent the standard deviation across five runs. Numbers
+are obtained with GPT2-large.
+Figure 9. t-SNE plot of the learned concept tokens for each task.
+Concept tokens that can be explained by similar tokens are anno-
+tated in the graph.
+to the ordering in most of the cases. An exception is the
+EmoC dataset, where our method has a very high variance.
+Lu et al. (2022) found that the order of the demonstration
+matter, and ordering with good performance cannot transfer
+between different-size LLMs. We suspect that the ordering
+only matters when there is a high variance when selecting
+demonstrations according to different random seeds.
+Qualitative results.
+In Figure 9, we provide a t-SNE
+(van der Maaten & Hinton, 2008) projection of the learned
+concept tokens. We can see that the tokens corresponding
+to semantically similar tasks are close together. We also
+compute the ten most similar tokens in the vocabulary to
+each concept token and summarize some of the tokens in
+the graph. The list of similar tokens for these concept tokens
+can be found in Table 10 in Appendix B.
+5. Related Work
+Heuristic solutions, such as selecting demonstrations based
+on the similarity between the demonstrations and test in-
+put (Liu et al., 2022; Su et al., 2022; Rubin et al., 2021)
+have been proposed. Lu et al. (2022) propose to reorder
+the demonstration based on the entropy of the predicted
+labels. In this paper, we use the similarity-based selection
+method as a baseline while do not include the label entropy-
+based reordering method as we show that the ordering of
+the demonstrations does not matter for our method.
+Previous research on the phenomenon of in-context learning
+in Transformers has identified a number of pre-training data
+distributions that can lead to the emergence of this capa-
+bility, including a Hidden Markov Model distribution (Xie
+et al., 2022) and a skewed Zipfian distribution with high
+burstiness (Chan et al., 2022). Other studies have sought to
+understand the underlying mechanisms of in-context learn-
+ing by making connections with gradient descent (von Os-
+wald et al., 2022), demonstrating that Transformers update
+smaller models encoded in their activations during inference
+(Aky¨urek et al., 2022), or formalizing it as an algorithm
+learning problem (Li et al., 2023). Chan et al. (2022) and
+Xie et al. (2022) demonstrate their findings using small
+Transformers on synthetic datasets, but it remains unclear if
+these results generalize to LLMs pre-trained on real-world
+text data. Similarly, Aky¨urek et al. (2022), Li et al. (2023)
+and von Oswald et al. (2022) perform experiments on the
+linear regression task, while the actual applications of in-
+context learning with LLMs are much more complex and
+varied. In contrast, we propose a simple explanation of in-
+context learning that can be verified with real-world LLMs
+like GPT2s and GPT3s on various NLP datasets.
+There are also works trying to understand in-context learn-
+ing from a more empirical perspective, Bansal et al. (2022)
+study the functionality of different attention heads during
+in-context learning, and found that only a small portion of
+model parameters is needed to preserve the in-context learn-
+ing capability. Min et al. (2022c) found that the demonstra-
+tions do not need ground truth labels for in-context learning
+to work, which we find is not entirely true for all tasks. On
+the other hand, chain-of-thoughts prompting (Wei et al.,
+2022; Zhou et al., 2022; Wang et al., 2022) find that pro-
+viding step-by-step explanations along with demonstrations
+improves in-context learning performance.
+6. Conclusion
+In this work, we endeavor to comprehend large language
+models through a Bayesian lens and posit them as implicit
+topic models that infer a latent conceptual variable from
+prompts. Motivated by this understanding, we propose a
+two-step algorithm that first extracts latent conceptual to-
+kens from a large language model and then selects demon-
+strations that have the greatest probability of predicting the
+corresponding conceptual tokens. The efficacy of our al-
+gorithm across various text classification datasets and GPT
+models validates our explanation of in-context learning. 3
+3We include a discussion of the limitation and the social impact
+of our paper in Appendix C and Appendix D.
+
+Reorder
+Not reorder
+90
+80
+70
+60
+50
+40
+30
+20
+10
+SST2
+FPB
+COLA
+Dbpedia
+Emoc
+Emos
+ETHOS-SO ETHOS-RSST2
+FPB
+COLA
+3 
+DBpedia
+ETHOS-SO
+2
+ETHOS-R
+Emoc
+910
+1
+Emos
+0
+Adverbs
+-1 
+40
+-2 
+-3 -
+-4
+-2 
+0
+2
+4Large Language Models Are Implicitly Topic Models
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+
+Large Language Models Are Implicitly Topic Models
+A. Proofs
+A.1. X � Y � θ direction
+Assumption A.1. (Assumption 2.1) Assume that PM(X) = P(X), and P d
+M(Y |θ, X) ∝ P(Y |θ, X) for X � Y � θ.
+Proposition A.2. (Proposition 2.2) If task d follows the X � Y � θ direction, arg maxy∈Y P d
+M(Y = y|θd, X) is the
+Bayes optimal classifier.
+Proof. Since the data generation of the task d can be written as Y = f(X, θd, ϵ), we have
+P d(Y |X) = P(Y |θd, X).
+And by Assumption A.1, we have
+arg max
+y∈Y
+P d
+M(Y = y|θd, X) = arg max
+y∈Y
+P(Y = y|θd, X).
+Thus arg maxy∈Y P d
+M(Y = y|θd, X) is the Bayes optimal classifier.
+Theorem A.3. (Theorem 2.3) If task d follows the X � Y � θ direction, then the in-context learning classifier
+arg max
+y∈Y
+P d
+M(Y = y|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)
+always has a higher or equal probability of misclassification to the Bayes optimal classifier arg maxy∈Y P d
+M(Y = y|θd, X).
+Equality only takes when
+∀x ∈ X, P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X = x) = 1.
+Proof. Recall that in Equation (1), we have
+P d
+M(Y |Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X) =
+�
+Θ
+P d
+M(Y |θ, X)P d
+M(θ|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X)dθ.
+By Proposition A.2, arg maxy∈Y P d
+M(Y = y|θd, X) is the Bayes optimal classifier. Let Cθ(X) = arg maxy∈Y P d
+M(Y =
+y|θ, X), then the risk is defined as the probability of misclassification
+R(Cθ) = P(Cθ(X) ̸= Y ) = EXY [1Cθ(X)̸=Y ].
+Denote the in-context learning classifier arg maxy∈Y P d
+M(Y = y|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X) by Ck(X). We then have
+R(Ck) = EXY [1Ck(X)̸=Y ] = EX[
+�
+y∈Y
+(1 − P d
+M(Y = y|θd, X))1Ck(X)=y].
+Such risk is minimized if and only if Ck(X) = Cθd(X), which only holds when P d
+M(θd|Xd
+1, Y d
+1 , ..., Xd
+k, Y d
+k , X = x) = 1
+for all x ∈ X.
+A.2. Y � X � θ direction
+Assumption A.4. Assume that PM(X) = P(X), and P d
+M(X|θ, Y ) ∝ P(X|θ, Y ) for the Y � X � θ direction.
+Proposition A.5. If task d follows the Y � X � θ causal direction, arg maxy∈Y P d
+M(X|θd, Y = y) is the Bayes optimal
+classifier when the label assignment is balanced.
+Proof. Since the data generation of the task d can be written as X = g(Y, θd, ϵ), we have
+P d(X|Y ) = P(X|θd, Y )
+
+Large Language Models Are Implicitly Topic Models
+When the label is balanced, i.e. P d(Y ) =
+1
+|Y|, we have
+P d(Y |X) = P d(X|Y )P d(Y )
+P(X)
+∝ P d(X|Y )
+And by Assumption A.4, we have
+arg max
+y∈Y
+P d
+M(X|θd, Y = y) = arg max
+y∈Y
+P(X|θd, Y = y).
+Thus arg maxy∈Y P d
+M(X|θd, Y = y) = arg maxy∈Y P d(Y = y|X) is the Bayes optimal classifier.
+Theorem A.6. If task d follows the Y � X � θ direction, then the in-context learning classifier
+arg max
+y∈Y
+P d
+M(X|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y = y)
+always has a higher or equal probability of misclassification to the Bayes optimal classifier arg maxy∈Y P d
+M(X|θd, Y = y).
+Equality only takes when
+∀y ∈ Y, P d
+M(θd|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y = y) = 1.
+Proof. This theorem can be proved similarly as Theorem A.3. Recall that in Equation (2), we have
+P d
+M(X|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y ) =
+�
+Θ
+P d
+M(X|θ, Y )P d
+M(θ|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y )dθ.
+By Proposition A.5,
+arg maxy∈Y P d
+M(X|θd, Y
+=
+y) is the Bayes optimal classifier.
+Let Cθ(X)
+=
+arg maxy∈Y P d
+M(X|θ, Y = y), then the risk is defined as the probability of misclassification
+R(Cθ) = P(Cθ(X) ̸= Y ) = EXY [1Cθ(X)̸=Y ].
+Denote the in-context learning classifier arg maxy∈Y P d
+M(X|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y = y) by Ck(X). We then have
+R(Ck) = EXY [1Ck(X)̸=Y ] = EX[
+�
+y∈Y
+(1 − P d
+M(X|θd, Y = y))1Ck(X)=y].
+Such risk is minimized if and only if Ck(X) = Cθd(X), which only holds when P d
+M(θd|Y d
+1 , Xd
+1, ..., Y d
+k , Xd
+k, Y = y) = 1
+for all y ∈ Y.
+A.3. Method
+Proposition A.7. (Proposition 3.1) When L(ˆθd) is minimized, P d
+M(Y |ˆθd, X) = P(Y |θd, X) for X � Y � θ, and
+P d
+M(X|ˆθd, Y ) = P(X|θd, Y ) for Y � X � θ. If θ is identifiable, then ˆθd = θd.
+Proof. The proof of this proposition is straightforward.
+Since
+L(ˆθd) = H(P(Y |θd, X)) + KL(P(Y |θd, X)||P d
+M(Y |ˆθd, X))
+when L(ˆθd) is minimized, we have P d
+M(Y |ˆθd, X) = P(Y |θd, X) for X � Y � θ, and P d
+M(X|ˆθd, Y ) = P(X|θd, Y ) for
+Y � X � θ. If θ is identifiable, this means ˆθd = θd.
+
+Large Language Models Are Implicitly Topic Models
+Table 1. Prompt template and label mapping for the datasets we use. Since almost all sentences from ETHOS contain offensive content,
+we mask out the key offensive words in the examples below.
+Dataset
+Prompt
+Label Mapping
+SST-2
+sentence: well worth revisiting as many times
+positive
+negative/positive
+FPB
+The company anticipates its turnover for the whole 2010 to
+surpass that of the previous year when it was EUR 67.1 million .
+positive
+negative/neutral/positive
+COLA
+It is this hat that I know the boy who is wearing.
+unacceptable
+acceptable/unacceptable
+DBPedia
+The Nucet River is a tributary of the Chiojdeanca
+River in Romania.
+NaturalPlace
+Album/Animal/Artist/Athlete/Building/Company/
+EducationalInstitution/Film/MeanOfTransportation/
+NaturalPlace/OfficeHolder/Plant/Village/WrittenWork
+EmoC
+fast i mean fastingis a way of skipping meals i mena
+you move on too fast
+others
+angry/happy/others/sad
+EmoS
+i feel this place was tragic
+sadness
+anger/fear/joy/love/sadness/surprise
+ETHOS-SO
+[Masked] should be removed from the face of the earth
+true
+false/true
+ETHOS-R
+I hate being a [Masked], wish I was a [Masked]
+and no [Masked] on earth existed
+false
+false/true
+B. Experiments
+Dateset. In Appendix B, we show how we process the text classification datasets into prompts. For each dataset, we take
+at most 16384 examples from the training set for training, and uniformly sample at most 1000 examples from the test
+set to test the in-context learning performance. In Table 2, we show the train size and test size we used for each dataset.
+We also list the set of diverse tasks trained with each dataset, which are denoted by their name in Huggingface datasets.4
+The license for SST2, ETHOS-SO and ETHOS-R is GNU General Public License v3. FPB is under a Creative Commons
+Attribution-NonCommercial-ShareAlike 3.0 Unported License. Notice that these two datasets are hate speech detection
+datasets for different kinds of hate speech and contain many offensive texts. COLA is excerpted from the published works
+available on the website, and the copyright (where applicable) remains with the original authors or publishers. DBpedia is
+under a Creative Commons Attribution-ShareAlike License and the GNU Free Documentation License. EmoC and EmoS
+should be used for educational and research purposes only.
+We run our experiments on A100, V100, and A6000 GPUs. We adopt a large portion of the code from the MetaICL
+repository (Min et al., 2022b)5. The training takes around 20 to 40 hours on a single GPU. We use a learning rate of 1e-4
+and a batch size of 16, and train for 10k steps in total.
+Results. In Table 3, we list the detailed results of our method and baselines with different LLMs on different datasets in
+Figure 2. The detailed results with instruction fine-tuned GPT3s are in Table 4, corresponding to Figure 4 in the main text.
+The detailed results with anti-causal direction (the opposite direction to what we described in Section 4 are in Table 5) are
+shown in Table 5, corresponding to Figure 3 in the main text. The detailed results with random words and random labels
+are shown in Table 6, corresponding to Figure 6 in the main text. The detailed results using the learned concept tokens as
+prefixes are shown in Table 7, corresponding to Figure 5 in the main text. The detailed results of k ablation study are shown
+in Table 8, corresponding to Figure 7 in the main text. The detailed results with and without reordering are shown in Table 9,
+corresponding to Figure 8 in the main text.
+We show the top ten similar tokens to some learned concept tokens in Table 10, as summarized in Figure 9 in the main text.
+4https://huggingface.co/docs/datasets/index
+5https://github.com/facebookresearch/MetaICL
+
+Large Language Models Are Implicitly Topic Models
+datset d
+train size
+test size
+task set S
+SST2 (glue-sst2)
+16384
+1000
+glue-cola/glue-mnli/glue-qqp/glue-mrpc/glue-qnli/glue-rte/glue-sst2/glue-wnli
+FPB (financial phrasebank)
+1811
+453
+glue-sst2/glue-mnli/math qa/sciq/social i qa/wino grande/glue-qqp/
+ag news/financial phrasebank/poem sentiment/anli/quarel/quartz/
+medical questions pairs/paws/dbpedia 14
+COLA (cola-sst2)
+8551
+1000
+glue-cola/glue-mnli/glue-qqp/glue-mrpc/glue-qnli/glue-rte/glue-sst2/glue-wnli
+DBpedia (dbpedia 14)
+16384
+1000
+glue-sst2/glue-mnli/math qa/sciq/social i qa/wino grande/glue-qqp/
+ag news/financial phrasebank/poem sentiment/anli/quarel/quartz/
+medical questions pairs/paws/dbpedia 14
+EmoC (emo)
+16384
+1000
+glue-sst2/amazon polarity/financial phrasebank/poem sentiment/
+yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion
+EmoS (emotion)
+16000
+1000
+glue-sst2/amazon polarity/financial phrasebank/poem sentiment/
+yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion
+ETHOS-SO (ethos-sexual orientation)
+346
+87
+glue-sst2/amazon polarity/financial phrasebank/poem sentiment/
+yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion
+ETHOS-R (ethos-religion)
+346
+87
+glue-sst2/amazon polarity/financial phrasebank/poem sentiment/
+yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion
+Table 2. Dataset details
+We also show histograms of the probability of each example predicting corresponding concept tokens in different datasets.
+We can see that the probability of prediction concept tokens can well differentiate examples in a dataset.
+C. Limitations and Future Work
+In this paper, we present an algorithm for selecting demonstrations that aims to provide empirical evidence for our proposed
+Bayesian explanation of in-context learning. However, it should be noted that the limitations of our experiments (only tested
+on eight text classification dataset) do not allow us to definitively conclude that our hypothesis, that language models (LLMs)
+are implicitly inferring latent concept variables from demonstrations, holds true for all possible tasks. Our method has been
+tested on multiple-choice problems such as math questions, and has been found to be ineffective in these types of tasks. This
+could be due to the fact that in-context learning operates differently in multiple-choice problems, or it may be a result of the
+current limitations of the latent concept learning algorithm. Additionally, while our experiments were conducted using the
+GPT family of LLMs, there are other pre-trained LLMs (e.g. OPT (Zhang et al., 2022), BLOOM (Scao et al., 2022)) that
+could also be used in future studies. However, due to time and computational constraints, these are not included in this paper.
+Furthermore, the theoretical guarantees of our explanation and algorithm are relatively weak, as a result of the need to
+balance theoretical compatibility with real-world situations. A key area for future work is to design a more robust latent
+concept learning algorithm that can provably identify the true latent concept variable to some extent. Additionally, the
+selection of the accompanying diverse tasks S is currently left to the discretion of the user. A more principled approach to
+constructing such a task set is needed in order to gain a deeper understanding of latent concept variables and to improve the
+latent concept learning algorithm.
+D. Social Impact
+The utilization of language models (LLMs) for specific tasks is often hindered by the high cost associated with training or
+fine-tuning them. However, the in-context learning paradigm offers a cost-effective and convenient alternative for utilizing
+the power of pretrained LLMs. Our work has demonstrated a significant improvement in performance of in-context learning
+through a relatively low-cost and simple approach, thus making the use of LLMs more accessible for individuals with
+limited resources.
+However, it is important to consider the broader implications of the increasing use of LLMs. As LLMs are not infallible and
+may make mistakes, it is crucial to explicitly warn users of the potential for misleading output and to regulate the distribution
+of LLMs in order to prevent any negative societal impact. Additionally, it is possible that LLMs could be intentionally
+misused, thus it is important to consider the ethical implications of their use and to take appropriate measures to mitigate
+
+Large Language Models Are Implicitly Topic Models
+Table 3. Accuracy of selected demonstration. Our demonstrations are selected using GPT2-large, and the same set of demonstrations is
+applied to all different LLMs. All LLMs are pre-trained only with the language modeling objective, while the pre-training data size of
+GPT2s is much smaller than GPT3s.
+LLM
+Method
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+Avg
+GPT2
+Random
+69.7 ± 1.8
+52.9 ± 2.3
+61.9 ± 1.4
+48.0 ± 0.7
+35.3 ± 1.7
+26.4 ± 1.0
+64.1 ± 4.8
+71.0 ± 1.8
+53.7
+(124M)
+Similar
+69.5 ± 0.6
+55.9 ± 1.7
+63.2 ± 1.2
+44.7 ± 3.1
+36.4 ± 2.0
+26.6 ± 1.3
+77.7 ± 2.7
+80.0 ± 3.7
+56.8
+Ours
+76.8 ± 2.9
+64.5 ± 3.2
+69.1 ± 0.2
+53.5 ± 2.95
+37.2 ± 11.1
+30.6 ± 4.8
+80.9 ± 1.9
+76.8 ± 2.6
+61.2
+GPT2-m
+Random
+70.8 ± 1.3
+52.0 ± 1.7
+57.8 ± 1.3
+49.3 ± 2.0
+34.2 ± 1.8
+34.2 ± 1.8
+76.3 ± 4.9
+74.7 ± 2.2
+56.2
+(355M)
+Similar
+75.0 ± 1.9
+57.7 ± 2.0
+57.5 ± 2.2
+47.9 ± 6.0
+37.2 ± 3.6
+35.2 ± 1.8
+86.9 ± 2.9
+84.6 ± 4.3
+60.3
+Ours
+81.2 ± 1.3
+59.3 ± 4.3
+69.0 ± 0.2
+52.9 ± 2.3
+40.4 ± 21.5
+37.2 ± 2.4
+83.7 ± 1.1
+76.8 ± 1.1
+62.6
+GPT2-l
+Random
+77.1 ± 1.2
+51.3 ± 2.4
+62.7 ± 0.8
+54.4 ± 0.9
+38.7 ± 2.1
+34.5 ± 1.2
+67.6 ± 4.3
+72.9 ± 2.8
+57.4
+(774M)
+Similar
+80.7 ± 1.6
+54.8 ± 3.8
+50.9 ± 1.4
+51.1 ± 5.2
+39.9 ± 2.6
+35.1 ± 2.1
+80.9 ± 2.8
+84.4 ± 2.6
+59.7
+Ours
+86.2 ± 1.4
+60.4 ± 2.5
+69.1 ± 0.2
+56.5 ± 3.2
+48.4 ± 17.0
+38.6 ± 2.8
+82.5 ± 1.5
+76.6 ± 1.2
+64.8
+GPT2-xl
+Random
+74.7 ± 0.9
+53.2 ± 1.9
+55.8 ± 1.6
+53.0 ± 1.9
+38.2 ± 1.5
+38.2 ± 1.5
+67.8 ± 6.4
+72.6 ± 4.1
+56.7
+(1.5B)
+Similar
+80.6 ± 1.3
+53.0 ± 2.5
+55.0 ± 2.5
+51.6 ± 5.9
+39.9 ± 2.0
+32.9 ± 2.1
+82.8 ± 2.2
+83.9 ± 4.5
+60
+Ours
+83.1 ± 3.6
+62.0 ± 2.5
+68.9 ± 0.2
+58.6 ± 3.3
+43.6 ± 16.4
+43.6 ± 16.4
+83.0 ± 1.3
+77.9 ± 1.3
+65.1
+GPT3-a
+Random
+76.9 ± 0.7
+56.6 ± 1.1
+53.1 ± 1.8
+62.1 ± 1.4
+38.6 ± 1.4
+27.7 ± 1.3
+65.5 ± 5.7
+74.0 ± 3.0
+56.8
+(350M)
+Similar
+78.7 ± 1.0
+52.2 ± 2.7
+53.1 ± 1.8
+54.6 ± 1.7
+42.4 ± 3.5
+37.2 ± 1.1
+84.1 ± 2.2
+87.8 ± 3.5
+61.3
+Ours
+85.4 ± 1.7
+61.9 ± 10.5
+58.2 ± 7.0
+64.0 ± 4.4
+43.0 ± 7.2
+37.9 ± 2.3
+84.4 ± 1.4
+78.9 ± 0.9
+64.2
+GPT3-b
+Random
+80.8 ± 0.6
+55.2 ± 3.3
+46.8 ± 2.0
+66.5 ± 1.4
+42.0 ± 0.7
+27.0 ± 1.2
+71.0 ± 4.6
+72.6 ± 3.1
+57.7
+(1.3B)
+Similar
+83.9 ± 1.3
+56.2 ± 2.3
+45.1 ± 1.8
+59.8 ± 1.8
+42.9 ± 3.5
+38.1 ± 1.7
+86.7 ± 3.0
+86.4 ± 3.0
+62.4
+Ours
+87.3 ± 2.0
+64.3 ± 5.9
+67.2 ± 0.9
+70.2 ± 3.2
+43.6 ± 13.0
+38.9 ± 5.0
+84.6 ± 0.9
+78.9 ± 1.2
+66.9
+GPT3-c
+Random
+84.2 ± 1.4
+52.6 ± 1.8
+59.1 ± 1.5
+70.6 ± 0.8
+44.3 ± 2.5
+32.3 ± 1.9
+77.5 ± 4.7
+77.5 ± 0.6
+62.3
+(6.7B)
+Similar
+85.7 ± 1.4
+62.2 ± 0.9
+58.0 ± 1.7
+62.2 ± 2.0
+47.4 ± 4.3
+39.8 ± 1.7
+89.2 ± 1.4
+89.7 ± 1.9
+66.8
+Ours
+88.8 ± 0.7
+64.1 ± 5.7
+69.0 ± 0.3
+73.6 ± 2.9
+50.3 ± 11.9
+43.1 ± 4.6
+86.2 ± 0.0
+78.2 ± 0.0
+69.2
+GPT3-d
+Random
+86.5 ± 0.9
+59.2 ± 2.4
+45.5 ± 2.8
+73.6 ± 1.9
+39.4 ± 0.7
+40.6 ± 1.7
+77.2 ± 2.6
+76.8 ± 3.5
+62.4
+(175B)
+Similar
+88.5 ± 0.8
+55.4 ± 3.3
+45.4 ± 1.5
+67.2 ± 1.8
+37.6 ± 1.6
+39.8 ± 1.4
+86.9 ± 2.4
+89.0 ± 3.8
+63.7
+Ours
+87.8 ± 3.4
+62.7 ± 3.3
+58.5 ± 8.2
+75.5 ± 2.4
+41.3 ± 3.6
+42.7 ± 3.9
+85.1 ± 0.0
+79.3 ± 0.0
+66.6
+Avg
+Random
+77.6
+54.1
+55.3
+59.7
+38.8
+32.6
+70.9
+74.0
+57.9
+Similar
+80.3
+55.9
+53.5
+54.9
+40.5
+35.6
+84.4
+85.7
+61.4
+Ours
+84.6
+62.4
+66.1
+63.1
+43.5
+39.1
+83.8
+77.9
+65.0
+Table 4. We test our method on instruction fine-tuned LLMs.
+LLM
+Method
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+Avg
+GPT3-a
+Random
+58.0 ± 0.9
+34.5 ± 1.8
+64.0 ± 1.0
+25.4 ± 1.2
+31.0 ± 2.3
+21.1 ± 1.5
+65.3 ± 6.9
+64.8 ± 4.3
+45.5
+Ours
+57.0 ± 1.9
+36.8 ± 4.9
+68.9 ± 0.1
+27.7 ± 3.1
+40.6 ± 8.6
+22.3 ± 2.0
+84.1 ± 2.1
+72.2 ± 4.4
+51.2
+GPT3-b
+Random
+73.3 ± 1.4
+52.5 ± 1.2
+64.6 ± 0.3
+50.8 ± 1.1
+46.3 ± 1.0
+32.2 ± 1.0
+37.9 ± 2.8
+39.5 ± 6.0
+49.6
+Ours
+76.5 ± 3.3
+60.9 ± 4.3
+67.0 ± 1.2
+51.5 ± 2.0
+50.0 ± 7.3
+34.9 ± 4.4
+58.2 ± 4.5
+48.3 ± 6.3
+55.9
+GPT3-c
+Random
+73.1 ± 1.7
+53.8 ± 2.0
+54.9 ± 0.7
+57.1 ± 0.9
+30.5 ± 1.3
+32.3 ± 1.3
+61.4 ± 2.4
+59.1 ± 2.4
+52.8
+Ours
+79.6 ± 2.0
+53.5 ± 8.1
+55.3 ± 2.4
+58.0 ± 1.3
+32.8 ± 19.8
+34.1 ± 5.3
+58.9 ± 6.8
+76.1 ± 3.5
+56
+any potential negative effects. We posit that these regulations and measures should be put in place at the time of distributing
+LLMs to ensure the safe and responsible use of these models. Furthermore, as we publicly release our code, we will also
+provide clear warnings and guidelines to users to ensure that the potential risks associated with the use of our method are
+fully understood and addressed.
+
+Large Language Models Are Implicitly Topic Models
+Table 5. We test random selection baseline with anti-causal direction.
+LLM
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+GPT2
+57.4 ± 1.9
+56.6 ± 2.1
+55.9 ± 1.7
+11.3 ± 1.0
+24.6 ± 2.4
+22.1 ± 1.1
+64.1 ± 4.8
+58.6 ± 5.5
+GPT2-m
+56.7 ± 1.6
+48.7 ± 2.1
+55.3 ± 1.8
+13.9 ± 1.2
+22.4 ± 1.9
+24.9 ± 2.3
+44.8 ± 1.9
+45.5 ± 3.5
+GPT2-l
+58.7 ± 0.7
+33.7 ± 1.3
+50.8 ± 1.6
+13.6 ± 1.3
+28.2 ± 3.6
+26.2 ± 2.7
+48.7 ± 3.7
+53.6 ± 5.3
+GPT2-xl
+54.2 ± 0.5
+46.8 ± 1.2
+50.6 ± 1.1
+12.6 ± 1.5
+31.4 ± 2.8
+25.9 ± 3.2
+65.5 ± 4.9
+61.8 ± 1.5
+GPT3-a
+55.8 ± 0.9
+58.9 ± 2.1
+51.6 ± 1.4
+14.3 ± 0.8
+54.2 ± 3.1
+27.7 ± 1.3
+49.2 ± 3.3
+54.9 ± 6.4
+GPT3-b
+64.4 ± 1.6
+58.9 ± 2.6
+53.4 ± 1.1
+14.6 ± 1.1
+52.0 ± 2.5
+27.0 ± 1.3
+48.3 ± 2.7
+51.0 ± 4.0
+GPT3-c
+78.2 ± 1.6
+52.3 ± 2.3
+53.7 ± 0.7
+23.0 ± 2.5
+49.1 ± 2.6
+32.2 ± 1.9
+57.9 ± 2.7
+64.1 ± 5.0
+Avg
+60.8
+50.8
+53
+14.8
+37.4
+26.6
+54.1
+55.6
+Table 6. We test our method with random words and random labels using GPT2-large.
+Method
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+Avg
+random words
+Random
+54.1 ± 4.2
+43.4 ± 1.9
+62.2 ± 4.9
+11.2 ± 0.9
+32.4 ± 5.2
+19.1 ± 1.8
+80.7 ± 4.8
+77.0 ± 3.6
+47.5
+Ours
+50.3 ± 1.3
+44.9 ± 4.2
+69.2 ± 0.2
+13.9±1.2
+37.8 ± 12.1
+23.5 ± 7.4
+86.0 ± 0.5
+77.9 ± 0.5
+50.5
+random labels
+Random
+51.5 ± 0.9
+32.5 ± 1.2
+49.3 ± 3.0
+6.7 ± 1.0
+25.1 ± 0.6
+17.2 ± 0.9
+48.0 ± 2.5
+56.8 ± 3.1
+35.9
+Ours
+49.6 ± 0.9
+36.2 ± 2.5
+49.3 ± 1.6
+6.6± 0.2
+24.7 ± 0.6
+16.6 ± 1.0
+51.0 ± 4.9
+48.7 ± 3.5
+35.3
+Table 7. Accuracy using concept tokens as prefixes.
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+90.3 ± 0.0
+86.1 ± 0.0
+75.0 ± 0.1
+92.6 ± 0.6
+57.3 ± 1.8
+53.8 ± 0.7
+86.2 ± 0.0
+78.2 ± 0.0
+Table 8. k ablation study using GPT2-large, without reordering.
+Method
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+Avg
+k = 4
+Random
+76.9 ± 0.7
+56.6 ± 1.1
+53.1 ± 1.8
+62.1 ± 1.4
+38.6 ± 1.4
+27.7 ± 1.3
+65.5 ± 5.7
+74.0 ± 3.0
+56.8
+Ours
+86.2 ± 1.4
+59.7 ± 2.8
+69.1 ± 0.2
+56.5 ± 3.2
+38.2 ± 21.8
+37.7 ± 2.5
+83.0 ± 1.3
+76.6 ± 1.2
+63.4
+k = 8
+Random
+79.9 ± 0.2
+57.1 ± 1.6
+51.3 ± 1.0
+66.5 ± 1.2
+37.6 ± 1.5
+36.2 ± 0.6
+68.5 ± 3.5
+72.9 ± 3.3
+58.8
+Ours
+87.0 ± 2.4
+59.9 ± 3.3
+55.3 ± 9.7
+67.0 ± 0.9
+39.9 ± 5.3
+38.8 ± 2.6
+77.0 ± 11.1
+78.9 ± 0.9
+63
+k = 16
+Random
+79.9 ± 1.1
+54.9 ± 2.7
+54.5 ± 2.8
+69.1 ± 1.1
+33.7 ± 2.2
+33.5 ± 1.4
+64.8 ± 4.0
+69.0 ± 3.2
+57.4
+Ours
+84.6 ± 1.9
+60.4 ± 6.4
+62.0 ± 7.0
+71.0 ± 1.9
+37.2 ± 6.1
+37.1 ± 2.2
+72.4 ± 7.6
+74.7 ± 4.7
+62.4
+Table 9. Reorder versus not reorder using our method, with GPT2-large.
+SST2
+FPB
+COLA
+DBpedia
+EmoC
+EmoS
+ETHOS-SO
+ETHOS-R
+Avg
+reorder
+86.2 ± 1.4
+60.4 ± 2.5
+69.1 ± 0.2
+56.5 ± 3.2
+48.4 ± 17.0
+38.6 ± 2.8
+82.5 ± 1.5
+76.6 ± 1.2
+64.8
+not reorder
+86.2 ± 1.4
+59.7 ± 2.8
+69.1 ± 0.2
+56.5 ± 3.2
+38.2 ± 21.8
+37.7 ± 2.5
+83.0 ± 1.3
+76.6 ± 1.2
+63.4
+
+Large Language Models Are Implicitly Topic Models
+Table 10. We list the top 10 similar words (tokens) to some of the learned concept tokens.
+concept token
+similar words
+FPB-2
+milo coordinate notify rendering benefiting routing EntityItem routed Messages Plot
+FPB-3
+unlocked updating deleting dropping damage updates drops Gained taken dropped
+FPB-4
+FX Safari Fixes advertisers Links Coins Operator marketers Guidelines
+FPB-5
+674 592 693 696 498 593 793 504 691 683
+COLA-1
+exha trunc curv fragmented elong iterator initialized bounds Iter filament
+COLA-2
+Sp spa contributed cerv borrower paper tiger Erica USH Schwartz
+COLA-7
+democr Barack WH ophobic neum Democrats Rachel WH Democrats
+DBpedia-4
+often impede blockade incarcerated LEASE pollutants pesticides uphe lawmakers fossils
+DBpedia-5
+categorized closes therapies antidepressant retrospective clinically physicians therapists randomized clinicians
+DBpedia-7
+JS provided Killed richness Compet Nevertheless Probably Proceedings horizontally
+ETHOS-SO-3
+Revolution Spread itu Million Pascal stabil Indy Georgian Figure resy
+ETHOS-R-2
+council Chocobo Shant uyomi aditional cumbers subur ThumbnailImage araoh Pharaoh
+ETHOS-R-8
+seems outlines emitted grin outline circuitry sized flips emits flipped
+ETHOS-R-9
+223 asel Cyrus Sith Scorpion Snape Jas Leia Ned Morty
+EmoC-6
+behavi checkpoints unintention crib eleph looph np mosquit blat pione
+EmoC-8
+depressed bullied choked stricken devastated unsuccessful cheated distraught troubled failing
+EmoS-1
+frightened rebellious depressed careless bullied restless reluctant distraught clumsy disgruntled
+EmoS-5
+obsessive crappy demonic delusions psychosis psychotic childish stupidity reckless insanity
+EmoS-7
+benevolent charismatic perfected volunte unintention pione innocuous fearless glamorous ruthless
+EmoS-9
+whispers pundits Sadly horribly curiously noticeably Sadly gaping painfully shockingly
+
+Large Language Models Are Implicitly Topic Models
+(a) SST2
+(b) FBP
+(c) COLA
+(d) DBpedia
+(e) EmoC
+(f) EmoS
+(g) ETHOS-SO
+(h) RTHOS-R
+Figure 10. Historgrams of the probability of train examples in each dataset predicting corresponding concept tokens.
+
+Histogramof SST2
+7
+-9
+5
+3
+2 -
+1 
+0
+0.24
+0.26
+0.28
+0.30
+0.32
+0.34
+0.36
+P(θ|X,Y)Histogram of FPB
+8
+6 -
+rcentage
+4
+2
+0
+0.020
+0.025
+0.030
+0.035
+0.040
+P(θ|X,Y)HistogramofCOLA
+6
+5 -
+4 -
+Percentage
+m
+2
+1 -
+0
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@@ -0,0 +1,2123 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf,len=2122
+page_content='Large Language Models Are Implicitly Topic Models:  Explaining and Finding Good Demonstrations for In-Context Learning  Xinyi Wang 1 Wanrong Zhu 1 William Yang Wang 1  Abstract  In recent years, pre-trained large language mod-  els have demonstrated remarkable efficiency in  achieving an inference-time few-shot learning ca-  pability known as in-context learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However,  existing literature has highlighted the sensitiv-  ity of this capability to the selection of few-shot  demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The underlying mechanisms by  which this capability arises from regular language  model pretraining objectives remain poorly under-  stood.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In this study, we aim to examine the in-  context learning phenomenon through a Bayesian  lens, viewing large language models as topic mod-  els that implicitly infer task-related information  from demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' On this premise, we pro-  pose an algorithm for selecting optimal demon-  strations from a set of annotated data and demon-  strate a significant 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5% improvement relative  to the random selection baseline, averaged over  eight GPT2 and GPT3 models on eight different  real-world text classification datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our em-  pirical findings support our hypothesis that large  language models implicitly infer a latent concept  variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Introduction  Recently, transformer-based (Vaswani et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2017) pre-  trained LLMs (LLMs) have demonstrated significant ad-  vancements in a variety of natural language processing  (NLP) tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' As the size of these LLMs increases, the  ability to perform in-context learning (Brown et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2020)  emerges, allowing models to achieve state-of-the-art or near  state-of-the-art performance by conditioning on a task de-  scription and a small number of demonstration examples  at inference time, without any need for updating model pa-  1Department of Computer Science, University of Cali-  fornia, Santa Barbara.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Correspondence to:  Xinyi Wang  <xinyi wang@ucsb.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='edu>.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Preprint.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  1Code:  https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='com/WANGXinyiLinda/  concept-based-demonstration-selection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  rameters (Brown et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Below is an example input  sequence for semantic analysis with in-context learning:  Great movie.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Positive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  The worst movie ever.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Can’t wait to see the second movie!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  The first two lines are two demonstrations, and the third line  is a test input.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We expect an LLM to output the correct label  Positive as a continuation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  In-context learning has been demonstrated to be an effective  technique for a wide range of natural language processing  tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However, it has been shown to be sensitive to the  choice, format, and even the order of the demonstrations  used (Perez et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2021;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Lu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This can make it  challenging to achieve optimal performance without signifi-  cant human effort invested in adjusting the format and selec-  tion of demonstration examples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Heuristic solutions, such  as selecting demonstrations based on the similarity between  the demonstrations and test input (Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Su et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=',  2022) have been proposed, but a comprehensive understand-  ing of why certain demonstrations are effective while others  are not remains elusive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Additionally, the mechanisms by  which LLMs acquire the ability to perform in-context learn-  ing through regular language model pre-training are not  fully understood.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Recent works on understanding in-context  learning provide valuable insights and theoretical results  (Xie et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Chan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Aky¨urek et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  von Oswald et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However, they are limited in scope,  focusing on synthetic experiments to validate their hypothe-  ses, while it remains unclear if these results generalize to  LLMs pre-trained on real-world text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  In this paper, we aim to develop a more systematic and  principled approach to optimizing the in-context learning  prompt, drawing on an in-depth understanding of the un-  derlying mechanisms of LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Specifically, we focus on  the choice of the few-shot demonstrations, while leaving  out the use of task description and keeping the format of  these demonstrations minimal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In this paper, we present  empirical evidence demonstrating that when performing in-  context learning, real-world LLMs such as GPT-2 (Radford  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2019) and GPT-3 (Brown et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2020) implicitly infer  a concept variable of the underlying task from the given  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='11916v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='CL]  27 Jan 2023  Large Language Models Are Implicitly Topic Models  demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This suggests that LLMs function in a sim-  ilar manner to topic models, but with the distinction that the  concept variable is learned implicitly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' A topic model mod-  els the text data distribution by assuming the presence of a  latent variable, known as the topic variable, which governs  the data generation process:  P(w1:T ) =  �  Θ  P(w1:T |θ)P(θ)dθ  Where θ ∈ Θ represents a potentially high dimensional  topic/concept variable, Θ is the space of the topic/concept  variable, and w1:T refers to the token sequence of a data  example, such as a sentence or document.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' A well-known  example of a topic model is Latent Dirichlet Allocation  (LDA) (Blei et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2003), which further assumes that each  token in the example is mutually independent of one another  given the topic variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' P(w1:T |θ) = �T  i=1 P(wi|θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  On the other hand, LLMs model text data according to the  general probabilistic decomposition:  P(w1:T ) =  T  �  i=1  P(wi|wi−1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', w1)  In this study, we focus specifically on generative LLMs  that have been pre-trained with a language model objective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  While in practice,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' LLMs generate new tokens based on  all previous tokens,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' we investigate whether a simplified  assumption similar to that of topic models can be made for  LLMs,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' which would take the form of:  PM(wt+1:T |w1:t) =  �  Θ  PM(wt+1:T |θ)PM(θ|w1:t)dθ  In this scenario,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' the generated tokens are assumed to be  conditionally independent of previous tokens,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' given the  topic/concept variable that acts like an approximate suffi-  cient statistic for the posterior information related to the  prompt w1:t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For in-context learning, this concept variable  would include the format and meaning of the task inferred  from the demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  By conditioning on the appropriate concept variable, LLMs  would generate the correct continuation with P(wt+1:T |θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  As LLMs do not explicitly learn a concept variable like  LDA-style topic models (Blei et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2003), we can instead  utilize this formulation under an Empirical Bayesian for-  mulation to extract the concept variable for use.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Drawing  inspiration from Lester et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2021), we introduce new con-  cept tokens to the vocabulary as prefixes and fine-tune only  the embedding of these new tokens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' By doing so, we can se-  lect demonstrations that are most likely to infer the concept  tokens of the task according to the LLM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Our findings indicate that the implicit-topic-model assump-  tion is effective for in-context learning when the direction  of inference is consistent with the causal direction of the  generation process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' To validate this empirically, we selected  demonstrations (w1:t in the equations) that are most likely to  infer or represent the desired latent concept variable (those  with the highest posterior probability P(θ|wt+1:T )) and  observed a significant improvement in performance when  using these demonstrations for in-context learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We observe that demonstrations selected based on one large  language model (GPT2-large) can be transferred to other  models (different size GPT2s and GPT3s) that have been  trained on the same pre-training objective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This behavior  of LLMs is likely a result of similar pre-training data dis-  tributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This finding is consistent with the discovery of  Xie et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022) that a pre-training distribution based on  a Hidden Markov Model with latent concept variables can  lead to the emergence of in-context learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  In this paper, we make the following contributions:  We provide a Bayesian explanation for how LLMs  (LLMs) perform in-context learning by formulating  them as implicit topic models;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We propose a cost-effective and efficient algorithm for  selecting suitable demonstrations that can be general-  ized to different LLMs;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Our explanation is supported by a comprehensive set  of empirical experiments on GPT2s and GPT3s with  various natural language processing datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Preliminaries  In the context of in-context learning, the prompt w1:t is  composed of several demonstrations and a test input.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The  generated tokens wt+1:T represent the prediction for the test  input.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our settings, notations, and theoretical analysis of  the problem will be discussed in further detail below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Notations and Problem Setting  Suppose the objective of our task is to predict a discrete  target variable Y ∈ Y, given a token sequence X ∈ X,  where X is the space of all possible token sequences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' θ ∈ Θ  is the latent concept variable, where Θ is the space of the  concept variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Note that, unlike the traditional topic  model, θ is not assumed to be discrete, and Θ is not assumed  to be finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' To define the data generation process, we posit  the existence of an underlying causal relation between X, Y ,  and θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We examine two potential directions of this causal  relation, namely X � Y � θ and Y � X � θ, which can  be represented mathematically as the following structural  equations:  Y = f(X, θ, ϵ)  X = g(Y, θ, ϵ)  Large Language Models Are Implicitly Topic Models  Here ϵ ∈ E is an independent noise variable, f : X × Θ ×  E → Y and g : Y × Θ × E → X are two deterministic  functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Furthermore, we denote the joint data distribution  by X, Y, θ ∼ P, and assume that Y is sampled from a uni-  form distribution over Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The distinction between these two  directions is crucial, as it allows us to utilize the direction  in which the child variable (Y or X) is independent of the  other variables, given its parents.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We hypothesize that the causal direction is dependent on  the nature of the task at hand.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For instance, in the task of  predicting the sentiment (Y ) of a movie review (X), it is  reasonable to assume that the opinion about the movie is  formed prior to the writing of the review, thus making Y  the cause of X, along with the task concept of “writing  a passage to express one’s opinion about the movie” (θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Conversely, for the task of identifying grammatical errors  (Y ) in a sentence (X), it is plausible that the sentence is not  intentionally written with errors, leading to the conclusion  that X is the cause of Y , along with the task concept of  “identifying grammatical errors in a sentence” (θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In the  rest of the paper, we will focus on the discussion of the  X � Y � θ direction, and leave a detailed discussion of  the other direction to the Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  In order to perform in-context learning with an LLM  (generically denoted by model label M),  we con-  dition on a fixed set of k demonstration examples  (Xd  1, Y d  1 ), (Xd  2, Y d  2 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k ) for a task d ∈ T , where  T is the space of all possible tasks, and Xd  i ∈ X, Y d  i ∈ Y  for all i ∈ [1, k].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In this approach, we do not include a task  description in the prompt, with the aim of focusing on the  examination of the demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  The data generation process of a task d can be written as:  Y d  i = f(Xd  i , θd, ϵ)  Here θd ∈ Θ is the value of the concept variable corre-  sponding to task d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' To naturally project Y into the token  space X, define injective mappings τ d : Y → X, which are  typically defined by human understanding of the task d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  for sentiment analysis, τ d map positive class to the token  “positive” and negative class to the token “negative”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Addi-  tionally, a delimiter token wd is defined, typically an empty  space or a new line token, to separate the demonstrations  when they are concatenated together.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We denote the LLM  output probability of X, Y , and θ, with the aforementioned  preprocessing applied, by P d  M:  PM(τ d(Y )|Xd  1, τ d(Y d  1 ), wd, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, τ d(Y d  k ), wd, X)  = P d  M(Y |Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Problem Analysis and Modling  We consider the scenario in which a small set of observed  data, denoted as Dd, is available, allowing for the selection  of the k most suitable demonstrations from it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Then, for any  incoming test example X, we have:  P d  M(Y |Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)  =  �  Θ  P d  M(Y |θ, X)P d  M(θ|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)dθ (1)  Here, we assume the sampling of the test example is in-  dependent of the sampling of the demonstrations, so Y is  independent of the demonstrations given θ and X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We also  assume that the pre-trained data distribution P d  M is a suitable  approximation of the assumed data distribution P:  Assumption 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Assume that PM(X) = P(X), and  P d  M(Y |θ, X) ∝ P(Y |θ, X) for X � Y � θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  It is important to note that while it is assumed that the  LLM perfectly learns the general text distribution, this is  not entirely accurate in practice.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' According to LeBrun et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  (2022), LLMs systematically underestimate rare text se-  quences, which constitute a significant portion of the long-  tail distribution of language.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Although this assumption is  adequate to achieve favorable empirical results, it is ex-  pected that more accurate language models will, in theory,  lead to improved outcomes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' With this assumption in mind,  the following is established:  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If task d follows the X � Y � θ direction,  then arg maxy∈Y P d  M(Y = y|θd, X) is the Bayes optimal  classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  In this case, only when P d  M(θ|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X) com-  pletely concentrate on θd, can the in-context learning clas-  sifier become the Bayes optimal classifier (Devroye et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=',  1996):  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If task d follows the X � Y � θ direction,  then the in-context learning classifier  arg max  y∈Y  P d  M(Y = y|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)  always has a higher or equal probability of misclassifica-  tion to the Bayes optimal classifier arg maxy∈Y P d  M(Y =  y|θd, X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Equality only takes when  ∀x ∈ X, P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X = x) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  A similar argument can be made for the Y � X � θ  direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Here, Equation (1) would become:  P d  M(X|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y )  =  �  Θ  P d  M(X|θ, Y )P d  M(θ|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y )dθ (2)  Note that Equation (1) and Equation (2) are very similar  to the direct and channel method introduced in Min et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  (2022a).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The detailed argument of the Y � X � θ direction  can be found in Appendix A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Large Language Models Are Implicitly Topic Models  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' An overview of our proposed two-phased algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Demonstration selection and latent concept learning share the same LLM  as demonstration selection needs to reuse the learned concept tokens, while at the in-context learning time, any other generative LLM  can be used.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Note that here we only illustrate the X � Y � θ direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The Y � X � θ direction can be illustrated similarly by  exchanging X and Y in the above figure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Method  In this section, we will first introduce how to estimate the  concept variable with an LLM and a collection of tasks  with training data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Then, we will discuss how to select an  optimal set of demonstrations for a task such that the in-  context learning classifier can become closer to the Bayes  optimal classifier, by using the learned concept variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Figure 1 is an overall illustration of our proposed method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Latent Concept Learning  To reveal the underlying latent concept variable θ within the  LLM M, we can utilize Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Building upon the  methodology proposed by Lester et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2021), for each spe-  cific task d, c new concept tokens (denoted as ˆθd) are added  to the original vocabulary of LLM M to represent the corre-  sponding task concept θd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Subsequently, the embedding of  these new tokens Enew(ˆθd) is fine-tuned while freezing the  remaining parameters of LLM M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The variable c is treated  as a hyperparameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In practice, in order to condition on  θd, the corresponding c concept tokens are appended to the  input X (or Y ) as demonstrated in the example provided  below, where c = 2:  <sentiment token 1><sentiment token 2>  Can’t wait to see the second movie!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  By giving the above input tokens, we ask the LLM to  predict the correct label Positive for us.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Note that  <sentiment token 1> here is just a label assigned to  the newly added concept token.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' It can be anything as long  as it does not overlap with the original vocabulary of LLM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  As reported in Lester et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2021), the larger the c is, the  better the classifier arg maxy∈Y P d  M(Y = y|ˆθd, X) would  be.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In practice, usually a small c (i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 10 to 50) would be  enough to obtain good performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  The fine-tuning objective would then be minimizing  L(ˆθd) = EX,Y [ℓ(X, Y ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' ˆθd)], where  ℓ(X, Y ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' ˆθd) =  �  − log P d  M(Y |ˆθd, X)  if X � Y � θ  − log P d  M(X|ˆθd, Y )  if Y � X � θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Theoretically, if we can minimize the above loss function,  a Bayes optimal classifier can be obtained, and the concept  tokens would be a reasonable delegate of the real latent  concept variable:  Proposition  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  When  L(ˆθd)  is  minimized,  P d  M(Y |ˆθd, X) = P(Y |θd, X) for X � Y  � θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If θ  is identifiable, then ˆθd = θd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We denote the LLM M with fine-tuned concept tokens by  M ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Since we add the concept tokens into the regular token  vocabulary, the raw LLM output of the probability of the  concept tokens PM ′(θ) would be in the token sequence  space X instead of the concept space Θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Since computing all  possible concept values in the concept space Θ is infeasible,  we propose to approximate the concept space Θ by sampling  a diverse subset of tasks S from the whole task space T .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Then the estimated concept probability of θd would be:  P d  M(θd) ≈ ˆP d  M ′(ˆθd) =  P d  M ′(ˆθd)  �  t∈S P t  M ′(ˆθt)  And the fine-tuning loss becomes �  d∈S L(θd).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Here, we  assume we have a reasonable-sized dataset D for each task  d, and we would be able to estimate the expectation EX,Y  by averaging over the training dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We summarize the  proposed algorithm in Algorithm 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Note that the embedding matrix of a generative LLM is  shared on both the input and output sides.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' So while we  only see the concept tokens on the input side at the training  time, they can be viewed as regular word tokens that can be  generated on the output side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Test Y  LLM  LLM  LLM  XkYk  Test X  Dataset  XY  θXY  YθXLarge Language Models Are Implicitly Topic Models  Algorithm 1 Latent concept learning  Input: dataset D associated with a set of tasks S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' LLM  M, number of concept tokens per task c, learning rate α,  and number of training steps L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Output: LLM M ′ with fine-tuned concept tokens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Add c|S| new tokens to the vocabulary;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Randomly initialize their embeddings Enew;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Freeze all parameters in M except Enew;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  for i = 1 to L do  Sample a random batch B in D;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Initialize gradient g ← 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  for each data point (x, y, d) in B do  g = g + ∂ℓ(X,Y ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='ˆθd)  ∂Enew  ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  end for  Enew = Enew − αg;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  end for  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Demonstration Selection  According to Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3, for a task d, to get a higher  accuracy at in-context learning time, we need to se-  lect demonstrations Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k  that maximize  P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X) for all X ∈ X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Then our  goal then becomes selecting demonstrations that can best  infer the task concept for all test inputs:  arg max  Xd  1 ,Y d  1 ,.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=',Xd  k,Y d  k  EX[P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)]  As test examples are sampled independent of the demonstra-  tions, and PM(X) = P(X) according to Assumption 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1,  we have  EX[P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)]  =  �  X∈X  P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)P(X)  =P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k )  Suppose each demonstration is also sampled independently.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Then we have:  P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k ) =  �k  i=1 P d  M(θd|Xd  i , Y d  i )  P d  M(θd)k−1  We assume that θ has a uniform prior.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Then our goal  becomes finding the top k demonstrations that maximize  ˆP d  M ′(ˆθd|Xd  i , Y d  i ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Note that, here, the independence between demonstra-  tions is a simplified assumption to make the search space  of (Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k ) smaller.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In practice, selected  demonstrations are likely correlated as some sets of demon-  strations may work well together but not necessarily work  well by themselves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However, it would be too expensive  to search the O(|Dd|k) combinations over the candidate  Algorithm 2 Demonstration selection  Input: dataset Dd for a task d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' LLM with fine-tuned  concept tokens M ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The number of demonstrations k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Output: A set of ordered demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  for each (Xd, Y d) in Dd do  Compute ˆP d  M(ˆθd|Xd, Y d);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  end for  Select top k examples with the largest ˆP d  M(θd|Xd, Y d),  denoted as (Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k );' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  for each permutation π do  Compute ˆP d  M(ˆθd|π((Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k )));' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  end for  Select  the  permutation  π  with  the  largest  ˆP d  M(ˆθd|π((Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k ))).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  set Dd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We would like to leave this as a future research  direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Also, as we are using an LLM to approximate the data dis-  tribution, the order of the demonstrations matters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We then  choose the order according to the posterior of the concept  tokens:  arg max  π∈Π  ˆP d  M(θd|π((Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k )))  (3)  Where π((Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k )) is a permutation of  (Xd  1, Y d  1 ), .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', (Xd  k, Y d  k ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Π is the set of all possible permuta-  tions of the k demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We summarize the proposed  algorithm in Algorithm 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Then we can use the selected demonstrations for in-context  learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In practice, we test the performance of the selected  demonstrations with a held-out test set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Experiments  Datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We conduct experiments on eight datasets from  five different types of NLP classification tasks: sentiment  analysis, linguistic analysis, topic classification, emotion  classification, and hate speech detection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For sentiment anal-  ysis, we choose the Stanford Sentiment Treebank (SST2)  dataset (Socher et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2013) from the GLUE benchmark  (Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2018) and the financial phrase bank (FPB)  dataset (Malo et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2014).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' SST2 is constructed based on  movie reviews labeled “positive” or “negative”, and FPB is  based on financial news labeled “positive”, “negative”, or  “neutral”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For linguistic analysis, we choose the Corpus of  Linguistic Acceptability (COLA) dataset (Warstadt et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=',  2018) from the GLUE benchmark, based on sentences col-  lected from linguistic books, labeled with “acceptable” or  “unacceptable”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For topic classification, we choose the DB-  pedia ontology classification dataset (Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2015),  based on DBpedia 2014 (Lehmann et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2015), labeled  with 14 different ontology classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For emotion classifica-  Large Language Models Are Implicitly Topic Models  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Accuracy of 4-shot in-context learning using demonstrations selected by our method and other baselines, averaged over eight  datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our demonstrations are selected using GPT2-large, and the same set of demonstrations is then applied to all other LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Accuracy of randomly selected demonstrations averaged  over seven different LLMs except for GPT3-davinci, using the  adopted causal direction and the anti-causal direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  tion, we choose the dataset from Chatterjee et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2019) and  Saravia et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2018), both of which are collected from Twit-  ter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Chatterjee et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2019) (EmoC) predict emotion given a  three-turn contextual dialogue, while Saravia et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2018)  predict emotion given a Twitter message with clear emotion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  For hate speech detection, we choose the online hate speech  detection dataset (ETHOS) (Mollas et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2020), collected  from online social media platforms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Here we detect two  types of hate speech: sexual orientation (ETHOS-SO) and  religion (ETHOS-R).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' While in Section 2, we assume that  all tasks share the same label space Y, here we relax such  assumption and allow a different number of labels for dif-  ferent tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We use minimal formatting to process each  example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' A detailed description of the datasets and our data  processing procedure can be found in Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Experiment settings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We adopt the X → Y ← θ causal di-  rection for the linguistic analysis and hate speech detection  type of tasks, as we usually do not intentionally use a lin-  guistic property when writing a sentence and the hate speech  is often not generated with a well-classified intention.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' On  the other hand, we adopt the Y → X ← θ causal direction  for the sentiment analysis, topic classification, and emotion  classification tasks, as we usually intend to write a piece of  text with some sentiment, or topic, or emotion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' From an  empirical perspective, we choose the direction that can give  a higher accuracy when using random demonstrations, as  shown in Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Without specification, we use k = 4 number of demonstra-  tions and c = 10 number of concept tokens per dataset for  our experiments, as the context length of GPT2 is 1024, and  a larger number of demonstrations may not be able to fit into  it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We use GPT2-large to learn the concept tokens and then  compute the probability of each candidate demonstration  example.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We select our demonstrations from a randomly  selected 100 example subset of the train set as the candidate  set Dd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For our method, we use the same set of demon-  strations selected by GPT2-large, for all other GPTs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We  test the performance of the selected demonstrations using  at most 1000 examples randomly sampled from the test set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Each experiment is repeated for five runs with different ran-  dom seeds (the randomness comes from the sampling of the  candidate set and the sampling of the test set).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We adopt a  large portion of the code from Min et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022b), which is  based on Huggingface (Wolf et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2019).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Baselines.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We consider the following baselines:  Uniform: for each test example, we uniformly select  k demonstrations from the candidate set D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Similar: According to Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022), demonstra-  tions semantically similar to the test example would  help.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Following their method, we use a pre-trained  sentence Transformer (Reimers & Gurevych, 2019) to  calculate the cosine similarity between the demonstra-  tions and test examples.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For each test example, we  choose the top k similar demonstrations from D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Main results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 Figure 2 shows our main in-context learn-  ing results averaged over all eight datasets, using the bare  language model pre-trained GPT2s and GPT3s, without any  instruction fine-tuning (Ouyang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022) or Reinforce-  ment Learning from Human Feedback (RLHF) (Stiennon  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2020).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our method significantly outperforms base-  lines on eight different LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The demonstrations selected  by our method are exclusively based on GPT2-large, while  the same set of demonstrations can be generalized to all  other LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We hypothesize that this is because of the  similar pre-training data distribution they have learned.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' To  verify this hypothesis, we also test the performance of our  2The complete results with standard deviations in this section  can be found in Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Uniform  Similar  Ours  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  60  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  GPT2  GPT2-medium  GPT2-large  GPT2-xl  GPT3-ada  GPT3-babbage  GPT3-curie  GPT3-davinci  (124M)  (355M)  (774M)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5B)  (350M)  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3B)  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7B)  (175B)CausalAnti-causal  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  70  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 53  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  SST2  FPB  COLA  Dbpedia  Emoc  Emos  ETHOS-SO ETHOS-RLarge Language Models Are Implicitly Topic Models  Figure 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Accuracy improvement of our proposed method versus  randomly selected demonstrations, with instruction fine-tuned  GPT3s, averaged over all eight datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Figure 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Accuracy of in-context learning using our method versus  the theoretical maximum accuracy obtained by using the learned  concept tokens as prefixes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Numbers are obtained with GPT2-  large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  selected demonstrations on instruction fine-tuned GPT3s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  As shown in Figure 4, our method’s improvement over ran-  dom selection is significantly smaller when using instruction  fine-tuned GPT3s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Ours versus optimal performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' As stated in Theo-  rem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3, the optimal performance of an in-context learn-  ing classifier should be the Bayesian optimal classifier  arg maxy∈Y P d  M(Y = y|θd, X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We compare the accuracy  of in-context learning using our method, and the accuracy of  using the learned concept tokens as prefixes, which approx-  imate the Bayes optimal classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' As shown in Figure 5,  our method comes close to the optimal accuracy on some  datasets while never becoming better, which empirically  verifies the conclusion in Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This indicates that  there are two ways to improve our method: the first is to  improve the performance of the optimal classifier, by intro-  ducing a better latent concept learning algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The other  way is to reduce the performance gap between our method  and the optimal classifier, by improving the demonstration  selection algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Effect of using ground truth labels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' According to Min  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022c), the ground truth label is not necessary for  demonstrations to have a good in-context learning perfor-  mance, which we found is not entirely true for all the  tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We compare our method with the randomly selected  demonstration baseline under three scenarios: (a) Original:  demonstrations with the correct labels;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (b) Random words:  using a random label projection map τ d instead of a mean-  ingful one.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', map each label to a fixed random word.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In  this case, the mapping from the input tokens X to the labels  Y is still preserved;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (c) Random labels: assign a random  Figure 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In-context learning accuracy of our method versus ran-  dom selection baseline, with (a) ground truth labels (original), (b)  random label mapping (random words), or random label assign-  ments (random label), averaged over all eight datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Numbers  are obtained with GPT2-large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Figure 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In-context learning accuracy of our method versus ran-  dom selection baseline, with different k, averaged over all eight  datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Numbers are obtained with GPT3-ada.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  label to each demonstration, with the original label projec-  tion map τ d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' As shown in Figure 6, by using a random label  projection map or randomly assigning the labels, the per-  formance of the randomly selected demonstration baseline  drops considerably.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' And randomize the label assignment  gives a larger performance drop than only using a random la-  bel projection map, which shows that the mapping between  X and Y in the demonstrations matters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This indicates that  in-context learning infers the mapping between X and Y  from the demonstrations instead of merely invoking some  learned function stored in the LLM parameters based on the  appearance of X and Y .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We also show that the demonstra-  tions selected by our method represent the X − Y mapping  better, as under the Random words condition, our method  performs better than the random selection baseline, while  our method does not improve the random selection baseline  under the Random labels condition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  k ablation study.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' While we use k = 4 demonstrations for  all the experiments above, we also test the effectiveness  of our method using different k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' As shown in Figure 7,  our method significantly outperforms the random selection  baseline with k = 4, 8, and 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Note that here we use  GPT3-ada instead of GPT2s, because the context length of  GPT2s is 1024, which could not fit in large ks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Also, we do  not reorder the selected demonstrations according to Equa-  tion (3), as we need to use GPT2-large to the reordering, and  it cannot fit in all the demonstrations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Instead, we order the  selected demonstrations from the largest ˆP d  M(θd|Xd, Y d)  to the smallest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Effect of demonstrations’ order.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In Figure 8, we show that  the demonstrations selected by our method are insensitive  ILM  instruct  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  GPT3-ada (350M)  GPT3-babbage (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3B)  GPT3-curie (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7B)Optimal■Ours  90.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  92.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  r  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  75  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  SST2  FPB  COLA  Dbpedia  EmoC  Emos  ETHOS-SO ETHOS-RUniform  ■Ours  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  47.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  Original  Random words  Random labelsUniform  Ours  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  63  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  k=4  k=8  k=16Large Language Models Are Implicitly Topic Models  Figure 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In-context learning accuracy of our method versus ran-  dom selection baseline, with and without reordering.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The red error  bars represent the standard deviation across five runs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Numbers  are obtained with GPT2-large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Figure 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' t-SNE plot of the learned concept tokens for each task.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Concept tokens that can be explained by similar tokens are anno-  tated in the graph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  to the ordering in most of the cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' An exception is the  EmoC dataset, where our method has a very high variance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Lu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022) found that the order of the demonstration  matter, and ordering with good performance cannot transfer  between different-size LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We suspect that the ordering  only matters when there is a high variance when selecting  demonstrations according to different random seeds.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Qualitative results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  In Figure 9, we provide a t-SNE  (van der Maaten & Hinton, 2008) projection of the learned  concept tokens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We can see that the tokens corresponding  to semantically similar tasks are close together.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We also  compute the ten most similar tokens in the vocabulary to  each concept token and summarize some of the tokens in  the graph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The list of similar tokens for these concept tokens  can be found in Table 10 in Appendix B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Related Work  Heuristic solutions, such as selecting demonstrations based  on the similarity between the demonstrations and test in-  put (Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Su et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Rubin et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2021)  have been proposed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Lu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022) propose to reorder  the demonstration based on the entropy of the predicted  labels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In this paper, we use the similarity-based selection  method as a baseline while do not include the label entropy-  based reordering method as we show that the ordering of  the demonstrations does not matter for our method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Previous research on the phenomenon of in-context learning  in Transformers has identified a number of pre-training data  distributions that can lead to the emergence of this capa-  bility, including a Hidden Markov Model distribution (Xie  et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022) and a skewed Zipfian distribution with high  burstiness (Chan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Other studies have sought to  understand the underlying mechanisms of in-context learn-  ing by making connections with gradient descent (von Os-  wald et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022), demonstrating that Transformers update  smaller models encoded in their activations during inference  (Aky¨urek et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022), or formalizing it as an algorithm  learning problem (Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2023).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Chan et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022) and  Xie et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022) demonstrate their findings using small  Transformers on synthetic datasets, but it remains unclear if  these results generalize to LLMs pre-trained on real-world  text data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Similarly, Aky¨urek et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022), Li et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2023)  and von Oswald et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022) perform experiments on the  linear regression task, while the actual applications of in-  context learning with LLMs are much more complex and  varied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In contrast, we propose a simple explanation of in-  context learning that can be verified with real-world LLMs  like GPT2s and GPT3s on various NLP datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  There are also works trying to understand in-context learn-  ing from a more empirical perspective, Bansal et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022)  study the functionality of different attention heads during  in-context learning, and found that only a small portion of  model parameters is needed to preserve the in-context learn-  ing capability.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Min et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (2022c) found that the demonstra-  tions do not need ground truth labels for in-context learning  to work, which we find is not entirely true for all tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' On  the other hand, chain-of-thoughts prompting (Wei et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=',  2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Zhou et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Wang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022) find that pro-  viding step-by-step explanations along with demonstrations  improves in-context learning performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Conclusion  In this work, we endeavor to comprehend large language  models through a Bayesian lens and posit them as implicit  topic models that infer a latent conceptual variable from  prompts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Motivated by this understanding, we propose a  two-step algorithm that first extracts latent conceptual to-  kens from a large language model and then selects demon-  strations that have the greatest probability of predicting the  corresponding conceptual tokens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The efficacy of our al-  gorithm across various text classification datasets and GPT  models validates our explanation of in-context learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' 3  3We include a discussion of the limitation and the social impact  of our paper in Appendix C and Appendix D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Reorder  Not reorder  90  80  70  60  50  40  30  20  10  SST2  FPB  COLA  Dbpedia  Emoc  Emos  ETHOS-SO ETHOS-RSST2  FPB  COLA  3  DBpedia  ETHOS-SO  2  ETHOS-R  Emoc  910  1  Emos  0  Adverbs  1  40  2  3 -  4  2  0  2  4Large Language Models Are Implicitly Topic Models  References  Aky¨urek, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Schuurmans, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
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+page_content=', Ma, T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
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+page_content=' What learning algorithm is in-context learn-  ing?' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' investigations with linear models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' arXiv preprint  arXiv:2211.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='15661, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Bansal, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
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+page_content=' Character-level convolu-  tional networks for text classification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Advances in neural  information processing systems, 28, 2015.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Zhou, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
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+page_content=', Wang,  X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
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+page_content=', Bousquet, O.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Le, Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', and Chi, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Least-to-most prompting enables complex reasoning in  Large Language Models Are Implicitly Topic Models  large language models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' arXiv preprint arXiv:2205.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='10625,  2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Large Language Models Are Implicitly Topic Models  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Proofs  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' X � Y � θ direction  Assumption A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (Assumption 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1) Assume that PM(X) = P(X), and P d  M(Y |θ, X) ∝ P(Y |θ, X) for X � Y � θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2) If task d follows the X � Y � θ direction, arg maxy∈Y P d  M(Y = y|θd, X) is the  Bayes optimal classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Since the data generation of the task d can be written as Y = f(X, θd, ϵ), we have  P d(Y |X) = P(Y |θd, X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  And by Assumption A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1, we have  arg max  y∈Y  P d  M(Y = y|θd, X) = arg max  y∈Y  P(Y = y|θd, X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Thus arg maxy∈Y P d  M(Y = y|θd, X) is the Bayes optimal classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3) If task d follows the X � Y � θ direction, then the in-context learning classifier  arg max  y∈Y  P d  M(Y = y|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)  always has a higher or equal probability of misclassification to the Bayes optimal classifier arg maxy∈Y P d  M(Y = y|θd, X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Equality only takes when  ∀x ∈ X, P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X = x) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Recall that in Equation (1), we have  P d  M(Y |Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X) =  �  Θ  P d  M(Y |θ, X)P d  M(θ|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X)dθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  By Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2, arg maxy∈Y P d  M(Y = y|θd, X) is the Bayes optimal classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Let Cθ(X) = arg maxy∈Y P d  M(Y =  y|θ, X), then the risk is defined as the probability of misclassification  R(Cθ) = P(Cθ(X) ̸= Y ) = EXY [1Cθ(X)̸=Y ].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Denote the in-context learning classifier arg maxy∈Y P d  M(Y = y|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X) by Ck(X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We then have  R(Ck) = EXY [1Ck(X)̸=Y ] = EX[  �  y∈Y  (1 − P d  M(Y = y|θd, X))1Ck(X)=y].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Such risk is minimized if and only if Ck(X) = Cθd(X), which only holds when P d  M(θd|Xd  1, Y d  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Xd  k, Y d  k , X = x) = 1  for all x ∈ X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Y � X � θ direction  Assumption A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Assume that PM(X) = P(X), and P d  M(X|θ, Y ) ∝ P(X|θ, Y ) for the Y � X � θ direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If task d follows the Y � X � θ causal direction, arg maxy∈Y P d  M(X|θd, Y = y) is the Bayes optimal  classifier when the label assignment is balanced.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Since the data generation of the task d can be written as X = g(Y, θd, ϵ), we have  P d(X|Y ) = P(X|θd, Y )  Large Language Models Are Implicitly Topic Models  When the label is balanced, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' P d(Y ) =  1  |Y|, we have  P d(Y |X) = P d(X|Y )P d(Y )  P(X)  ∝ P d(X|Y )  And by Assumption A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4, we have  arg max  y∈Y  P d  M(X|θd, Y = y) = arg max  y∈Y  P(X|θd, Y = y).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Thus arg maxy∈Y P d  M(X|θd, Y = y) = arg maxy∈Y P d(Y = y|X) is the Bayes optimal classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If task d follows the Y � X � θ direction, then the in-context learning classifier  arg max  y∈Y  P d  M(X|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y = y)  always has a higher or equal probability of misclassification to the Bayes optimal classifier arg maxy∈Y P d  M(X|θd, Y = y).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Equality only takes when  ∀y ∈ Y, P d  M(θd|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y = y) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This theorem can be proved similarly as Theorem A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Recall that in Equation (2), we have  P d  M(X|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y ) =  �  Θ  P d  M(X|θ, Y )P d  M(θ|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y )dθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  By Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5,  arg maxy∈Y P d  M(X|θd, Y  =  y) is the Bayes optimal classifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Let Cθ(X)  =  arg maxy∈Y P d  M(X|θ, Y = y), then the risk is defined as the probability of misclassification  R(Cθ) = P(Cθ(X) ̸= Y ) = EXY [1Cθ(X)̸=Y ].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Denote the in-context learning classifier arg maxy∈Y P d  M(X|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y = y) by Ck(X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We then have  R(Ck) = EXY [1Ck(X)̸=Y ] = EX[  �  y∈Y  (1 − P d  M(X|θd, Y = y))1Ck(X)=y].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Such risk is minimized if and only if Ck(X) = Cθd(X), which only holds when P d  M(θd|Y d  1 , Xd  1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', Y d  k , Xd  k, Y = y) = 1  for all y ∈ Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Method  Proposition A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' (Proposition 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1) When L(ˆθd) is minimized, P d  M(Y |ˆθd, X) = P(Y |θd, X) for X � Y � θ, and  P d  M(X|ˆθd, Y ) = P(X|θd, Y ) for Y � X � θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If θ is identifiable, then ˆθd = θd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The proof of this proposition is straightforward.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Since  L(ˆθd) = H(P(Y |θd, X)) + KL(P(Y |θd, X)||P d  M(Y |ˆθd, X))  when L(ˆθd) is minimized, we have P d  M(Y |ˆθd, X) = P(Y |θd, X) for X � Y � θ, and P d  M(X|ˆθd, Y ) = P(X|θd, Y ) for  Y � X � θ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' If θ is identifiable, this means ˆθd = θd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Large Language Models Are Implicitly Topic Models  Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Prompt template and label mapping for the datasets we use.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Since almost all sentences from ETHOS contain offensive content,  we mask out the key offensive words in the examples below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Dataset  Prompt  Label Mapping  SST-2  sentence: well worth revisiting as many times  positive  negative/positive  FPB  The company anticipates its turnover for the whole 2010 to  surpass that of the previous year when it was EUR 67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 million .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  positive  negative/neutral/positive  COLA  It is this hat that I know the boy who is wearing.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  unacceptable  acceptable/unacceptable  DBPedia  The Nucet River is a tributary of the Chiojdeanca  River in Romania.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  NaturalPlace  Album/Animal/Artist/Athlete/Building/Company/  EducationalInstitution/Film/MeanOfTransportation/  NaturalPlace/OfficeHolder/Plant/Village/WrittenWork  EmoC  fast i mean fastingis a way of skipping meals i mena  you move on too fast  others  angry/happy/others/sad  EmoS  i feel this place was tragic  sadness  anger/fear/joy/love/sadness/surprise  ETHOS-SO  [Masked] should be removed from the face of the earth  true  false/true  ETHOS-R  I hate being a [Masked],' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' wish I was a [Masked]  and no [Masked] on earth existed  false  false/true  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Experiments  Dateset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In Appendix B, we show how we process the text classification datasets into prompts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' For each dataset, we take  at most 16384 examples from the training set for training, and uniformly sample at most 1000 examples from the test  set to test the in-context learning performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In Table 2, we show the train size and test size we used for each dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We also list the set of diverse tasks trained with each dataset, which are denoted by their name in Huggingface datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  The license for SST2, ETHOS-SO and ETHOS-R is GNU General Public License v3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' FPB is under a Creative Commons  Attribution-NonCommercial-ShareAlike 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 Unported License.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Notice that these two datasets are hate speech detection  datasets for different kinds of hate speech and contain many offensive texts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' COLA is excerpted from the published works  available on the website, and the copyright (where applicable) remains with the original authors or publishers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' DBpedia is  under a Creative Commons Attribution-ShareAlike License and the GNU Free Documentation License.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' EmoC and EmoS  should be used for educational and research purposes only.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We run our experiments on A100, V100, and A6000 GPUs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We adopt a large portion of the code from the MetaICL  repository (Min et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022b)5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The training takes around 20 to 40 hours on a single GPU.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We use a learning rate of 1e-4  and a batch size of 16, and train for 10k steps in total.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' In Table 3, we list the detailed results of our method and baselines with different LLMs on different datasets in  Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The detailed results with instruction fine-tuned GPT3s are in Table 4, corresponding to Figure 4 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  The detailed results with anti-causal direction (the opposite direction to what we described in Section 4 are in Table 5) are  shown in Table 5, corresponding to Figure 3 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The detailed results with random words and random labels  are shown in Table 6, corresponding to Figure 6 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The detailed results using the learned concept tokens as  prefixes are shown in Table 7, corresponding to Figure 5 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The detailed results of k ablation study are shown  in Table 8, corresponding to Figure 7 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' The detailed results with and without reordering are shown in Table 9,  corresponding to Figure 8 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We show the top ten similar tokens to some learned concept tokens in Table 10, as summarized in Figure 9 in the main text.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  4https://huggingface.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='co/docs/datasets/index  5https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='com/facebookresearch/MetaICL  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='Large Language Models Are Implicitly Topic Models  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='datset d  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='train size  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='test size  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='task set S  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='SST2 (glue-sst2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='16384  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1000  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-cola/glue-mnli/glue-qqp/glue-mrpc/glue-qnli/glue-rte/glue-sst2/glue-wnli  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='FPB (financial phrasebank)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1811  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='453  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-sst2/glue-mnli/math qa/sciq/social i qa/wino grande/glue-qqp/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='ag news/financial phrasebank/poem sentiment/anli/quarel/quartz/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='medical questions pairs/paws/dbpedia 14  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='COLA (cola-sst2)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8551  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1000  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-cola/glue-mnli/glue-qqp/glue-mrpc/glue-qnli/glue-rte/glue-sst2/glue-wnli  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='DBpedia (dbpedia 14)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='16384  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1000  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-sst2/glue-mnli/math qa/sciq/social i qa/wino grande/glue-qqp/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='ag news/financial phrasebank/poem sentiment/anli/quarel/quartz/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='medical questions pairs/paws/dbpedia 14  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='EmoC (emo)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='16384  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1000  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-sst2/amazon polarity/financial phrasebank/poem sentiment/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='EmoS (emotion)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='16000  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1000  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-sst2/amazon polarity/financial phrasebank/poem sentiment/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='ETHOS-SO (ethos-sexual orientation)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='346  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='87  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-sst2/amazon polarity/financial phrasebank/poem sentiment/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='ETHOS-R (ethos-religion)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='346  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='87  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='glue-sst2/amazon polarity/financial phrasebank/poem sentiment/  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='yelp polarity/glue-cola/blimp/ag news/dbpedia 14/ethos/emo/emotion  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Dataset details  We also show histograms of the probability of each example predicting corresponding concept tokens in different datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  We can see that the probability of prediction concept tokens can well differentiate examples in a dataset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Limitations and Future Work  In this paper, we present an algorithm for selecting demonstrations that aims to provide empirical evidence for our proposed  Bayesian explanation of in-context learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However, it should be noted that the limitations of our experiments (only tested  on eight text classification dataset) do not allow us to definitively conclude that our hypothesis, that language models (LLMs)  are implicitly inferring latent concept variables from demonstrations, holds true for all possible tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our method has been  tested on multiple-choice problems such as math questions, and has been found to be ineffective in these types of tasks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' This  could be due to the fact that in-context learning operates differently in multiple-choice problems, or it may be a result of the  current limitations of the latent concept learning algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Additionally, while our experiments were conducted using the  GPT family of LLMs, there are other pre-trained LLMs (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' OPT (Zhang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022), BLOOM (Scao et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=', 2022)) that  could also be used in future studies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However, due to time and computational constraints, these are not included in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Furthermore, the theoretical guarantees of our explanation and algorithm are relatively weak, as a result of the need to  balance theoretical compatibility with real-world situations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' A key area for future work is to design a more robust latent  concept learning algorithm that can provably identify the true latent concept variable to some extent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Additionally, the  selection of the accompanying diverse tasks S is currently left to the discretion of the user.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' A more principled approach to  constructing such a task set is needed in order to gain a deeper understanding of latent concept variables and to improve the  latent concept learning algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Social Impact  The utilization of language models (LLMs) for specific tasks is often hindered by the high cost associated with training or  fine-tuning them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' However, the in-context learning paradigm offers a cost-effective and convenient alternative for utilizing  the power of pretrained LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our work has demonstrated a significant improvement in performance of in-context learning  through a relatively low-cost and simple approach, thus making the use of LLMs more accessible for individuals with  limited resources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  However, it is important to consider the broader implications of the increasing use of LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' As LLMs are not infallible and  may make mistakes, it is crucial to explicitly warn users of the potential for misleading output and to regulate the distribution  of LLMs in order to prevent any negative societal impact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Additionally, it is possible that LLMs could be intentionally  misused, thus it is important to consider the ethical implications of their use and to take appropriate measures to mitigate  Large Language Models Are Implicitly Topic Models  Table 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Accuracy of selected demonstration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Our demonstrations are selected using GPT2-large, and the same set of demonstrations is  applied to all different LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' All LLMs are pre-trained only with the language modeling objective, while the pre-training data size of  GPT2s is much smaller than GPT3s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  LLM  Method  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  Avg  GPT2  Random  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  71.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  (124M)  Similar  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  Ours  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='95  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  GPT2-m  Random  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  (355M)  Similar  75.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  47.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  Ours  81.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  GPT2-l  Random  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  (774M)  Similar  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  Ours  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  GPT2-xl  Random  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5B)  Similar  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  60  Ours  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  GPT3-a  Random  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  (350M)  Similar  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  Ours  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  GPT3-b  Random  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  71.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3B)  Similar  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  Ours  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  GPT3-c  Random  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7B)  Similar  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  47.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  89.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  89.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  Ours  88.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  GPT3-d  Random  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  (175B)  Similar  88.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  89.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  Ours  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  75.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  41.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  42.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  Avg  Random  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  70.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  Similar  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  85.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  Ours  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  Table 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We test our method on instruction fine-tuned LLMs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  LLM  Method  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  Avg  GPT3-a  Random  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  Ours  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  40.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  GPT3-b  Random  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  Ours  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  GPT3-c  Random  73.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  Ours  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  34.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  56  any potential negative effects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We posit that these regulations and measures should be put in place at the time of distributing  LLMs to ensure the safe and responsible use of these models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Furthermore, as we publicly release our code, we will also  provide clear warnings and guidelines to users to ensure that the potential risks associated with the use of our method are  fully understood and addressed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Large Language Models Are Implicitly Topic Models  Table 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We test random selection baseline with anti-causal direction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  LLM  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  GPT2  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  GPT2-m  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  45.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  GPT2-l  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  28.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  GPT2-xl  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  46.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  31.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  61.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  GPT3-a  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  GPT3-b  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  GPT3-c  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  52.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  Avg  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  53  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  Table 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We test our method with random words and random labels using GPT2-large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Method  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  Avg  random words  Random  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  43.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  80.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  47.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  Ours  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  44.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9±1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  23.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  random labels  Random  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  Ours  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  49.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  24.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  16.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  35.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  Table 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Accuracy using concept tokens as prefixes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  90.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  75.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  92.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  Table 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' k ablation study using GPT2-large, without reordering.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  Method  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  Avg  k = 4  Random  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  27.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  65.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  Ours  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  k = 8  Random  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  51.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  66.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  36.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  68.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  Ours  87.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  55.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3 ± 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  67.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  39.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  77.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  78.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  63  k = 16  Random  79.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  54.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  33.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  57.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  Ours  84.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  71.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='9  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  72.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6  74.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7  62.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  Table 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' Reorder versus not reorder using our method, with GPT2-large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  SST2  FPB  COLA  DBpedia  EmoC  EmoS  ETHOS-SO  ETHOS-R  Avg  reorder  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  60.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  48.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4 ± 17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  82.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  64.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  not reorder  86.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  59.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  69.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='1 ± 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  56.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5 ± 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  38.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2 ± 21.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='8  37.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='7 ± 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='5  83.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='0 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='3  76.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='6 ± 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='2  63.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='4  Large Language Models Are Implicitly Topic Models  Table 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content=' We list the top 10 similar words (tokens) to some of the learned concept tokens.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
+page_content='concept token  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/rdFKT4oBgHgl3EQf0i6X/content/2301.11916v1.pdf'}
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+Frailty Model with Change Point for Survival Analysis
+Masahiro Kojima∗1,2 and Shunichiro Orihara3
+1Kyowa Kirin Co., Ltd
+2The Institute of Statistical Mathematics
+3Tokyo Medical University
+January 12, 2023
+Abstract
+We propose a novel frailty model with change points applying random effects to a Cox proportional hazard model
+to adjust the heterogeneity between clusters. Because the frailty model includes random effects, the parameters are
+estimated using the expectation-maximization (EM) algorithm. Additionally, our model needs to estimate change
+points; we thus propose a new algorithm extending the conventional estimation algorithm to the frailty model with
+change points to solve the problem. We show a practical example to demonstrate how to estimate the change
+point and random effect. Our proposed model can be easily analyzed using the existing R package. We conducted
+simulation studies with three scenarios to confirm the performance of our proposed model. We re-analyzed data
+of two clinical trials to show the difference in analysis results with and without random effect. In conclusion, we
+confirmed that the frailty model with change points has a higher accuracy than the model without the random
+effect. Our proposed model is useful when heterogeneity needs to be taken into account. Additionally, the absence
+of heterogeneity did not affect the estimation of the regression coefficient parameters.
+Keywords: change point; Cox proportional hazard model; EM algorithm; frailty model; random effect
+1
+Introduction
+Cox proportional hazard model is one of the primary analysis methods for time-to-event data. However, in recent
+years, there has been a case in which the assumption of proportional hazard does not hold in time-to-event data in
+some trials of immune checkpoint inhibitors such as nivolumab [1]. Immune checkpoint inhibitor (test drug group)
+shows a survival curve similar to the control group because events occur in a population less likely to respond to
+the test drug up to a point. On the other hand, after the point, the decrease in the survival probability of the
+test drug group became slower; the survival curve of the test drug group then moves away from that of the control
+group. Therefore, the assumption of proportional hazard may hold about each survival curve before and after the
+point. We call the point “change point” in this paper.
+To analyze these events accurately, the Cox proportional hazard model with change points is a valuable method.
+Various types of research have been conducted on the Cox proportional hazard model with change points [2–8].
+Liang et al. (1990) [2] proposed the proportional hazard model with one change point. Pons (2002) [3] extended
+Liang’s model to time-dependent covariates and proved the consistency of the estimators of coefficient parameters
+and the estimated change point. Liu et al. (2008) [4] and He et al. (2013) [5] proposed the maximal score tests
+for detecting change points using a simple Monte Carlo approach. Ozaki and Ninomiya (2022) [8] proposed a novel
+information criterion to determine the number of the best change points.
+Cluster effects are commonly assumed in various research fields (McNeish and Kelley, 2019 [9]). For instance, in
+clinical research, there are clusters of primary diseases, clinical facilities, and severity of interest disease. Commonly,
+the cluster effects are included in assumed statistical models as random effects. The random effects capture cluster
+specific variation, and fixed effects (e.g. interested treatment effects) which are not affected by the clusters can
+∗Address: Biometrics Department, R&D Division, Kyowa Kirin Co., Ltd.
+Otemachi Financial City Grand Cube, 1-9-2 Otemachi,
+Chiyoda-ku, Tokyo, 100-004, Japan. Tel: +81-3-5205-7200
+E-Mail: masahiro.kojima.tk@kyowakirin.com
+1
+arXiv:2301.04387v1  [stat.ME]  11 Jan 2023
+
+be estimated more precisely. A frailty model is a Cox proportional hazard model that accounts for heterogeneity
+between clusters. The frailty model has various previous works (c.f. Klein (1992) [10]; Vaida and Xu, 2000 [11]),
+however, change points has not yet to be considered.
+In this study, we propose a novel frailty model with change points applying random effects to a Cox proportional
+hazard model to adjust the heterogeneity between clusters. Because the frailty model includes random effects,
+the parameters are estimated using the expectation-maximization (EM) algorithm proposed by Klein (1992) [10].
+Additionally, our model needs to estimate change points. We propose a new algorithm extending the conventional
+estimation algorithm to the frailty model with change points to solve the problem. Our proposed model can be
+easily analyzed using the existing R package. We show a practical example that shows how to estimate the change
+point and random effect. To confirm the performance of our proposed model, we conduct simulation studies with
+three scenarios. In addition, we re-analyzed data from two clinical trials to show the difference in the results with
+and without random effect.
+This paper is organized as follows.
+Section 2 describes the proposed frailty model with change point and
+introduces the estimation method of the model. Section 3 presents a practical example to demonstrate how to
+estimate the change point and random effect of proposed model. Section 4 describes the setting and results of the
+computer simulations. Section 5 presents the results of analysis of data from two published clinical trials. Section
+6 provides a discussion of the results. The R program files used to analyze the simulation results and clinical trials
+are included in the Supplemental Material.
+2
+Methods
+We assume that there are M(≥ 2) clusters, the sample size is N, Ymi is a time-to-event of subject i for m-th cluster,
+and xmi is a vector of q-dimensional covariates for m-th cluster. Ymi can be right censored; the observation data
+Tmi is min(Ymi, Cmi), where Cmi is a censoring time. We assume that Cmi is independent of the other random
+variables that is the special case of the type I censoring (see Kalbfleisch and Prentice, 2002 [12]). We assume
+that there are K change points. The frailty model with change points considered in this paper is defined by giving
+coefficient parameters between each change point,
+λ(tmi; xmi, βk, vkm, τk) = λ0(tmi)vkm exp
+�
+βT
+k xmi
+�
+I(τk−1 < tmi ≤ τk),
+(1)
+where λ0(·) is a nonparametric hazard function, vkm is a random effect on m-th cluster for interval (τk−1, τk], βk
+is a vector of q-dimensional parameters for interval (τk−1, τk], and τk is an unknown change point for time point k.
+The K change points hold 0 = τ0 < τ1 < · · · < τK < τK+1 = T, in which T is the follow-up period. We assume
+that the distribution of vkm is the gamma distribution with the shape
+1
+θk and the rate
+1
+θk . Under this setting,
+the mean and variance of vkm are 1 and θk, respectively. To simplify the notation, let β = (βT
+1 , . . . , βT
+K, βT
+K+1)T ,
+τ = (τ1, . . . , τK)T , and θ = (θ1, . . . , θK, θK+1)T .
+From here, we consider a proposed estimating procedure. Under the settings, the likelihood function becomes
+l(λ0, β, τ, θ) = l1(λ0, β, τ) +
+K
+�
+k=1
+l2(θk).
+(2)
+where
+l1(λ0, β, τ) =
+K
+�
+k=1
+M
+�
+m=1
+Nm
+�
+i=1
+�
+δmi
+�
+log(λ0(tmi)) + βT
+k xmi
+�
+− vkm exp(βT
+k xmi) (Λ0(tmi) − Λ0(τk−1))
+�
+I(τk−1 < tmi ≤ τk),
+(3)
+and
+l2(θk) = −M
+� 1
+θk log(θk) + log
+�
+Γ
+� 1
+θk
+���
++
+M
+�
+m=1
+�� 1
+θk + Dkm − 1
+�
+log(vmk) − vmk
+θk
+�
+.
+(4)
+where Nm is the sample size on the m-th cluster, δmi = I(Tmi = Ymi) and Dkm = �
+i∈Ek δmi, Ek is the set
+of subject number to which the time-to-event in interval (τj−1, τj]. l1(λ0, β, τ) is the likelihood function for the
+Cox proportional hazard model and change points.
+l2(θk) is the likelihood function for the frailty.
+Since the
+parameters cannot be estimated analytically because of the random effects, we consider the extension of Klein
+(1992)[9]. Moreover, because Klein’s algorithm is intuitively straightforward, the extension is simple to apply to
+2
+
+our proposed frailty model with change points. The EM algorithm is as follows. First, to deal with the unobserved
+random effect, the E-step calculates the expected values of the random effect.
+The E-step
+The conditional distribution on the observed data is the gamma with shape parameter Akm =
+1
+θk + Dkm and
+rate parameter Bkm =
+1
+θk + �
+i∈Ek Λ0(tmi) exp(βkxmi)I(τk−1 < tmi ≤ τk). The conditional likelihood function is
+obtained by replacing vkm in the likelihood function with Akm
+Bkm . The initial value of θk is 1. The initial value of βk
+is the estimator of the standard Cox proportional hazard model with change points.
+The M-step
+In the M-step, the estimator of the parameters that maximizes the conditional likelihood function in the E-step is
+computed. For the conditional likelihood function of β and τ, the following profile likelihood function can be given
+through the estimation of nonparametric hazards ˆΛ.
+ˆΛ0(tmi) =
+�
+r:tmr≤tmi
+dmr
+�
+j:tmi<tmj ˆvkm exp(βkxmj)I(τk−1 < tmj ≤ τk),
+(5)
+dmr is the number of event at tmr. β and τ are estimated using the following partial likelihood function,
+pl1(β, τ) =
+k
+�
+k=1
+M
+�
+m=1
+Nm
+�
+i=1
+�
+δmiβT
+k xmi − dmi log
+�
+� �
+j:ti<tj
+ˆvkm exp(βT
+k xjm)
+�
+�
+�
+I(τk−1 < tj ≤ τk),
+(6)
+where ˆvkm =
+Akm
+Bkm .
+The estimator of θk is obtained by maximizing the conditional likelihood function on the
+observed data,
+cl2(θk) = −M
+� 1
+θk log(θk) + log
+�
+Γ
+� 1
+θk
+���
++
+M
+�
+m=1
+�� 1
+θk + Dkm − 1
+�
+(log(Akm) − log(Bkm)) −
+Akm
+θkBkm
+�
+(7)
+The candidate of change point τk is chosen from each time-to-event Ymi because the change point is considered
+as the event point that may change the slope of the Cox regression in this model. Hence, for each τk, the actual
+time-to-event is input. β and θ are then calculated. We fit all time-to-event combinations to the change point τk
+and compute estimators �β of β from the equation (6) and �θ of θ from the equation (7) for each fixed change point.
+The maximum likelihood estimator is the combination of �β, �τ, and �θ that maximizes the likelihood function (2),
+where �τ is input actual times-to-events.
+3
+Practical example
+We demonstrate the analysis of change points. We create the example dataset shown in Table 1.
+3
+
+Table 1: Example dataset
+Placebo Group
+Treatment Group
+ID
+ST
+Censor
+Cluster
+ID
+ST
+Censor
+Cluster
+1
+10
+Yes
+1
+16
+10
+Yes
+1
+2
+25
+No
+1
+17
+15
+Yes
+1
+3
+30
+No
+1
+18
+25
+No
+1
+4
+45
+No
+2
+19
+40
+No
+2
+5
+50
+No
+2
+20
+45
+No
+2
+6
+55
+Yes
+2
+21
+60
+Yes
+2
+7
+60
+No
+3
+22
+65
+Yes
+3
+8
+65
+No
+3
+23
+70
+No
+3
+9
+70
+Yes
+3
+24
+75
+No
+3
+10
+75
+No
+1
+25
+80
+Yes
+1
+11
+80
+No
+1
+26
+85
+No
+1
+12
+85
+No
+2
+27
+90
+Yes
+2
+13
+90
+Yes
+2
+28
+95
+No
+2
+14
+95
+No
+3
+29
+100
+Yes
+3
+15
+100
+Yes
+3
+30
+100
+Yes
+3
+ST: survival time (Week)
+First, we introduce the analysis of a single change point and no random effect. The set of candidate change points
+consists of actual times-to-event. Data for the 12 candidate points of change point τ1 are (25, 30, 40, 45, 50, 60, 65, 70, 75, 80, 85, 95, 100).
+The partial likelihood function with the unknown parameter β = (β1, β2)T for each τj is
+pl(β, τ1) =
+30
+�
+i=1
+{(I(0 < ti ≤ τ1)β1 + I(τ1 < ti ≤ 100)β2)xi}
+− log
+� �
+m∈R1
+exp(β1xm)
+�
+− log
+� �
+m∈R2
+exp(β2xm)
+�
+.
+(8)
+R1 is the risk set for ti ≥ 0. However, when ti ≥ τ1, the data are treated as censored data, R2 is the risk set for
+ti ∈ [τ1, 100]. For each change point, we calculate the estimator �β maximizing the partial likelihood function. β1
+and β2 can be computed independently. The combination of �β and ˆτ that maximizes the partial likelihood function
+is the maximum estimator. The maximum likelihood estimator was �β = (0.07, −0.76) and ˆτ = 50. Data analysis
+was performed using coxph function of the survival package in R. For detailed information on the algorithms, please
+refer to the supplemental material.
+Next, we show the analysis results of the frailty model with one change point. The partial likelihood is
+pl1(β, τ1) =
+3
+�
+m=1
+Nm
+�
+i=1
+�
+δmiβT
+k xmi − dmi log
+�
+� �
+j:ti<tj
+ˆvkm exp(βT
+k xjm)
+�
+�
+�
+I(τk−1 < tj ≤ τk),
+(9)
+and
+cl2(θ1) = −3
+� 1
+θ1 log(θ1) + log
+�
+Γ
+� 1
+θ1
+���
++
+3
+�
+m=1
+�� 1
+θ1 + D1m − 1
+�
+(log(A1m) − log(B1m)) −
+A1m
+θ1B1m
+�
+,
+cl2(θ2) = −3
+� 1
+θ2 log(θ2) + log
+�
+Γ
+� 1
+θ2
+���
++
+3
+�
+m=1
+�� 1
+θ1 + D2m − 1
+�
+(log(A2m) − log(B2m)) −
+A2m
+θ2B2m
+�
+.
+(10)
+We input 50 to τ1, D11 = 3, D12 = 4, D13 = 0, D21 = 3, D22 = 2, and D23 = 5. From the coxph function in R,
+the maximum likelihood estimators were easily calculated �β = (−0.35, −1.56), ˆτ = 80, and �θ = (0.00, 1.78). Note
+that ˆθ1 was not 0 but a very small value. When survival time was biased by clusters, adjusting for the random
+effect resulted in different change point estimates compared with the no random effect model. The survival curve
+for each group and change points are shown in Figure 1.
+4
+
++
++
++
++
++
++
++
++
++
++
++
+0.00
+0.25
+0.50
+0.75
+1.00
+0
+25
+50
+75
+100
+Weeks
+Survival probability
+Group
+Treatment
+Placebo
+τ 1=50
+τ 1=80
+Figure 1: Survival curves and change points of example data
++ means censored. The red line and red letters are the change points of the frailty model with one change point. The dark blue dotted
+line and dark blue letters are the change points of the Cox proportional hazard with one change point.
+4
+Simulation Study
+We evaluated the performance of the frailty model with change points. We assume that the sample size is 500, and
+the four category cluster is randomly assigned from (1, 2, 3, 4) with a probability of 0.25, xmi is randomly assigned
+0 or 1 with a probability of 0.5, the change point is 250, the follow-up period is 600, β = (β0, β1)T = (0, 0.5)T , and
+the non-informative censors occur a probability of 0.1. The number of simulations is 10,000. We prepared three
+scenarios. Scenario 1 has no frailty. The survival data are generated from exp(β0xim) × Exponential
+�
+1
+300
+�
+up to
+the change point and exp(β1xim) × Exponential
+�
+1
+300
+�
+after the change point. Scenario 2 has the frailty v1m and
+v2m generated from Gamma(0.1, 0.1). The survival data are generated from v1m exp(β1xim) × Exponential
+�
+1
+300
+�
+up to the change point and v2m exp(β2xim) × Exponential
+�
+1
+300
+�
+after the change point. Scenario 3 is the case in
+which the parameter of Gamma distribution in Scenario 2 changed to 0.2. The evaluation index for the simulation is
+bias and mean squared error (MSE). The bias is the average of estimator for each simulation − the true parameter
+value. The MSE is the average of the squared error of the difference between the estimators and true parameter
+values for each simulation. The simulation program is included in the supplemental material.
+4.1
+Simulation Results
+The simulation results are shown in Table 2. When there was no random effect in Scenario 1, the estimated results
+of the random effects are close to zero in the frailty model. The MSEs for �β and ˆτ1 were smaller in the frailty
+model. In Scenarios 2 and 3, the MSE of the change point was improved by adjusting for the variation effect. The
+change point bias was larger for the frailty model.
+5
+
+Table 2: Simulation results
+Parameter
+CP without random effect
+Frailty model
+Scenario 1 (θ1 = θ2 = 0)
+Bias
+MSE
+Bias
+MSE
+β1
+-0.067
+0.045
+-0.042
+0.036
+β2
+0.071
+0.057
+0.022
+0.052
+τ1
+14.7
+7958.8
+25.7
+7921.4
+θ1
+-
+-
+-0.010
+0.001
+θ2
+-
+-
+-0.012
+0.001
+Scenario 2 (θ1 = θ2 = 0.1)
+Bias
+MSE
+Bias
+MSE
+β1
+-0.067
+0.047
+-0.023
+0.032
+β2
+0.049
+0.055
+0.007
+0.049
+τ1
+18.5
+8278.1
+19.0
+6840.9
+θ1
+-
+-
+0.086
+0.009
+θ2
+-
+-
+-0.016
+0.020
+Scenario 3 (θ1 = θ2 = 0.2)
+Bias
+MSE
+Bias
+MSE
+β1
+-0.067
+0.047
+-0.020
+0.030
+β2
+0.026
+0.054
+-0.008
+0.046
+τ1
+22.6
+8722.9
+26.6
+6346.9
+θ1
+-
+-
+0.179
+0.036
+θ2
+-
+-
+-0.039
+0.057
+CP: Cox proportional hazard model with change point, Frailty model: Frailty model with change point. Red letter: MSE result is
+superior when the frailty is taken into account.
+5
+Clinical Trials
+We show how the frailty model behaves when applied to data from two clinical trials.
+5.1
+Re-analysis of data of a clinical trial on primary biliary cholangitis
+We included data from a clinical trial on primary biliary cholangitis (PBC); this was a placebo-controlled randomized
+trial that included 72 patients in the D-penicillamine group and 62 patients in the placebo group [13]. There is
+stage (S1: no progression, S2: mild progression, S3: moderate progression, and S4: advanced progression) as the
+cluster. In the D-penicillamine group, the number of S1 is 9, the number of S2 is 26, the number of S3 is 29, and
+the number of S4 is 8. In the placebo group, the number of S1 is 3, the number of S2 is 18, the number of S3 is 32,
+and the number of S4 is 9. The survival curves are shown in Figure 2. The survival curves crossed near the 10-year
+time point.
+6
+
+++++
++++++++++++++ ++ ++ +++ +++ ++
++++
++
+++++++
++++
+++
++ ++++
++ +
++
+++ +
++++++++ +
++
++
+++++++ ++++++
++
+++
++
++
++ +
++
+++++
++
++ ++++
+++
+0.00
+0.25
+0.50
+0.75
+1.00
+0.0
+2.5
+5.0
+7.5
+10.0
+12.5
+Years
+Survival probability
+Group
+D−penicillamine
+Placebo
+τ 1=7.58
+τ 1=7.66
+Figure 2: Survival curves of cases in the PBC study
++ means censored. The red line and red letters are the change points of the frailty model with one change point. The dark blue dotted
+line and dark blue letters are the change points of the Cox proportional hazard with one change point.
+For the Cox proportional hazard model with one change point, �β = (0.61, −0.54)T and τ1 = 7.58. For the
+frailty model with one change point, �β = (0.73, −0.19)T , τ1 = 7.66, and �θ = (0.66, 1.70)T . The data before the
+change point had a small random effect, but after the change point, the random effect was large and the value of
+ˆβ2 changed depending on the change point. The change point did not change markedly, but it shifted back a bit to
+a point in time by taking into account the random effect.
+5.2
+Re-analysis of data of a clinical trial on malignant glioma
+We included data from a clinical trial on malignant glioma (MG); the placebo-controlled randomized trial contained
+110 patients in the group of patients treated with chemotherapeutic agents incorporated into biodegradable polymers
+(polymer) and 112 patients in the placebo group [14]. There is tumor histopathology at implementation (path)
+(P1: glioblastoma, P2: anaplastic astrocytoma, P3: oligodendroglioma, P4: other) as the cluster. For the polymer
+group, the number of P1 is 76, the number of P2 is 14, the number of P3 is 15, and the number of P4 is 5. For the
+placebo group, the number of P1 is 73, the number of P2 is 16, the number of P3 is 20, and the number of P4 is 3.
+The survival curves are shown in Figure 3.
+7
+
++
+++
+++++
++
++
+++
+++
++
++
+0.00
+0.25
+0.50
+0.75
+1.00
+0
+50
+100
+150
+200
+Weeks
+Survival probability
+Group
+Polymer
+Placebo
+τ 1=32.57
+τ 1=30.14
+Figure 3: Survival curves of cases in the MG study
++ means censored. The red line and red letters are the change points of the frailty model with one change point. The dark blue dotted
+line and dark blue letters are the change points of the Cox proportional hazard with one change point.
+For the Cox proportional hazard model with one change point, �β = (−0.44, 0.18)T and τ1 = 30.14. For the
+frailty model with one change point, �β = (−0.45, 0.18)T , τ1 = 32.57, and �θ = (0.40, 0.08)T . Because the random
+effects are small, the estimators remained almost unchanged.
+6
+Discussion
+We propose the novel frailty model with change points to adjust the heterogeneity between clusters. There are
+clusters of primary diseases, clinical facilities, severity of interest disease, and so on. Our proposed model can be
+easily analyzed using the coxph function and frailty option. We confirmed that the accuracy of the estimation is
+increased by considering heterogeneity. Our simulation studies showed that the accuracy of change point estimation
+deteriorated because of heterogeneity, and the accuracy of estimation was improved using the frailty model. We
+included the R program code of analyses for the practical example, simulation, and two clinical trials in the
+Supplementary Materials. From the simulation study, we confirmed that adding frailty in all estimators for all
+scenarios resulted in smaller MSEs. Increasing the size of the random effect confirmed that the estimated change
+point of the Cox proportional hazard model with the change point model has a larger MSE. This suggests that the
+random effect affects the estimation accuracy of the change point. In the frailty model with the change point, the
+MSE of the change point estimator became smaller as the random effect increased. The accuracy of data estimation
+increased as the random effects were adjusted. The bias of the average estimated change points is larger for the
+frailty model, but the MSE is very large that we considered the difference in bias between the models to be within
+the margin of error. In the re-analysis of data from the PBC trial, the random effect size was more significant in the
+interval where the survival function is crossed. We confirmed that the estimates of the parameters of the regression
+coefficients change when the random effect is taken into account. In the re-analysis of data from the MG trial, the
+estimation results did not differ regardless of the presence or absence of frailty because of the small variate effects.
+Thus, this analysis confirmed that our model does not deviate from the estimation results of the Cox proportional
+hazard model with a change point when the variate effects are small. In conclusion, we confirmed that the frailty
+model with change points has higher accuracy than the model without the random effect. Our proposed model
+can be easily analyzed using the existing R package. Our proposed model is useful when heterogeneity needs to
+be taken into account. Additionally, the absence of heterogeneity did not affect the estimation of the regression
+coefficient parameters.
+Author Contributions. MK analyzed the example data, simulation datasets, and two clinical trial data and
+wrote the manuscript. OS proposed the research theme, reviewed and corrected the manuscript.
+8
+
+Acknowledgements.
+MK would like to thank Associate Professor Hisashi Noma for his encouragement and
+helpful suggestions. The authors would like to thank PhD student Ryoto Ozaki for his helpful comments.
+References
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+[12] Kalbfleisch JD and Prentice RL. The statistical analysis of failure time data. John Wiley & Sons, 2011.
+[13] Neuberger J, Christensen E, Portmann B, and et al. Double blind controlled trial of d-penicillamine in patients
+with primary biliary cirrhosis. Gut, 26(2):114–119, 1985.
+[14] Brem H, Piantadosi S, Burger PC, and et al.
+Placebo-controlled trial of safety and efficacy of intraop-
+erative controlled delivery by biodegradable polymers of chemotherapy for recurrent gliomas. The Lancet,
+345(8956):1008–1012, 1995.
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+
diff --git a/u9E3T4oBgHgl3EQfNwnN/content/tmp_files/load_file.txt b/u9E3T4oBgHgl3EQfNwnN/content/tmp_files/load_file.txt
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf,len=492
+page_content='Frailty Model with Change Point for Survival Analysis  Masahiro Kojima∗1,2 and Shunichiro Orihara3  1Kyowa Kirin Co.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=', Ltd  2The Institute of Statistical Mathematics  3Tokyo Medical University  January 12, 2023  Abstract  We propose a novel frailty model with change points applying random effects to a Cox proportional hazard model  to adjust the heterogeneity between clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Because the frailty model includes random effects, the parameters are  estimated using the expectation-maximization (EM) algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Additionally, our model needs to estimate change  points;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' we thus propose a new algorithm extending the conventional estimation algorithm to the frailty model with  change points to solve the problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We show a practical example to demonstrate how to estimate the change  point and random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our proposed model can be easily analyzed using the existing R package.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We conducted  simulation studies with three scenarios to confirm the performance of our proposed model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We re-analyzed data  of two clinical trials to show the difference in analysis results with and without random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In conclusion, we  confirmed that the frailty model with change points has a higher accuracy than the model without the random  effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our proposed model is useful when heterogeneity needs to be taken into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Additionally, the absence  of heterogeneity did not affect the estimation of the regression coefficient parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Keywords: change point;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Cox proportional hazard model;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' EM algorithm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' frailty model;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' random effect  1  Introduction  Cox proportional hazard model is one of the primary analysis methods for time-to-event data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' However, in recent  years, there has been a case in which the assumption of proportional hazard does not hold in time-to-event data in  some trials of immune checkpoint inhibitors such as nivolumab [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Immune checkpoint inhibitor (test drug group)  shows a survival curve similar to the control group because events occur in a population less likely to respond to  the test drug up to a point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' On the other hand, after the point, the decrease in the survival probability of the  test drug group became slower;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' the survival curve of the test drug group then moves away from that of the control  group.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Therefore, the assumption of proportional hazard may hold about each survival curve before and after the  point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We call the point “change point” in this paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  To analyze these events accurately, the Cox proportional hazard model with change points is a valuable method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Various types of research have been conducted on the Cox proportional hazard model with change points [2–8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Liang et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' (1990) [2] proposed the proportional hazard model with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Pons (2002) [3] extended  Liang’s model to time-dependent covariates and proved the consistency of the estimators of coefficient parameters  and the estimated change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Liu et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' (2008) [4] and He et al.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' (2013) [5] proposed the maximal score tests  for detecting change points using a simple Monte Carlo approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Ozaki and Ninomiya (2022) [8] proposed a novel  information criterion to determine the number of the best change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Cluster effects are commonly assumed in various research fields (McNeish and Kelley, 2019 [9]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For instance, in  clinical research, there are clusters of primary diseases, clinical facilities, and severity of interest disease.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Commonly,  the cluster effects are included in assumed statistical models as random effects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The random effects capture cluster  specific variation, and fixed effects (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' interested treatment effects) which are not affected by the clusters can  ∗Address: Biometrics Department, R&D Division, Kyowa Kirin Co.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=', Ltd.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Otemachi Financial City Grand Cube, 1-9-2 Otemachi,  Chiyoda-ku, Tokyo, 100-004, Japan.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Tel: +81-3-5205-7200  E-Mail: masahiro.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='kojima.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='tk@kyowakirin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='com  1  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='04387v1  [stat.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='ME]  11 Jan 2023  be estimated more precisely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' A frailty model is a Cox proportional hazard model that accounts for heterogeneity  between clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The frailty model has various previous works (c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='f.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Klein (1992) [10];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Vaida and Xu, 2000 [11]),  however, change points has not yet to be considered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  In this study, we propose a novel frailty model with change points applying random effects to a Cox proportional  hazard model to adjust the heterogeneity between clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Because the frailty model includes random effects,  the parameters are estimated using the expectation-maximization (EM) algorithm proposed by Klein (1992) [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Additionally, our model needs to estimate change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We propose a new algorithm extending the conventional  estimation algorithm to the frailty model with change points to solve the problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our proposed model can be  easily analyzed using the existing R package.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We show a practical example that shows how to estimate the change  point and random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' To confirm the performance of our proposed model, we conduct simulation studies with  three scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In addition, we re-analyzed data from two clinical trials to show the difference in the results with  and without random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  This paper is organized as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Section 2 describes the proposed frailty model with change point and  introduces the estimation method of the model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Section 3 presents a practical example to demonstrate how to  estimate the change point and random effect of proposed model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Section 4 describes the setting and results of the  computer simulations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Section 5 presents the results of analysis of data from two published clinical trials.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Section  6 provides a discussion of the results.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The R program files used to analyze the simulation results and clinical trials  are included in the Supplemental Material.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  2  Methods  We assume that there are M(≥ 2) clusters, the sample size is N, Ymi is a time-to-event of subject i for m-th cluster,  and xmi is a vector of q-dimensional covariates for m-th cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Ymi can be right censored;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' the observation data  Tmi is min(Ymi, Cmi), where Cmi is a censoring time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We assume that Cmi is independent of the other random  variables that is the special case of the type I censoring (see Kalbfleisch and Prentice, 2002 [12]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We assume  that there are K change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The frailty model with change points considered in this paper is defined by giving  coefficient parameters between each change point,  λ(tmi;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' xmi, βk, vkm, τk) = λ0(tmi)vkm exp  �  βT  k xmi  �  I(τk−1 < tmi ≤ τk),  (1)  where λ0(·) is a nonparametric hazard function, vkm is a random effect on m-th cluster for interval (τk−1, τk], βk  is a vector of q-dimensional parameters for interval (τk−1, τk], and τk is an unknown change point for time point k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The K change points hold 0 = τ0 < τ1 < · · · < τK < τK+1 = T, in which T is the follow-up period.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We assume  that the distribution of vkm is the gamma distribution with the shape  1  θk and the rate  1  θk .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Under this setting,  the mean and variance of vkm are 1 and θk, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' To simplify the notation, let β = (βT  1 , .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' , βT  K, βT  K+1)T ,  τ = (τ1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' , τK)T , and θ = (θ1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' , θK, θK+1)T .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  From here, we consider a proposed estimating procedure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Under the settings, the likelihood function becomes  l(λ0, β, τ, θ) = l1(λ0, β, τ) +  K  �  k=1  l2(θk).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  (2)  where  l1(λ0, β, τ) =  K  �  k=1  M  �  m=1  Nm  �  i=1  �  δmi  �  log(λ0(tmi)) + βT  k xmi  �  − vkm exp(βT  k xmi) (Λ0(tmi) − Λ0(τk−1))  �  I(τk−1 < tmi ≤ τk),  (3)  and  l2(θk) = −M  � 1  θk log(θk) + log  �  Γ  � 1  θk  ���  +  M  �  m=1  �� 1  θk + Dkm − 1  �  log(vmk) − vmk  θk  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  (4)  where Nm is the sample size on the m-th cluster, δmi = I(Tmi = Ymi) and Dkm = �  i∈Ek δmi, Ek is the set  of subject number to which the time-to-event in interval (τj−1, τj].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' l1(λ0, β, τ) is the likelihood function for the  Cox proportional hazard model and change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  l2(θk) is the likelihood function for the frailty.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Since the  parameters cannot be estimated analytically because of the random effects, we consider the extension of Klein  (1992)[9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Moreover, because Klein’s algorithm is intuitively straightforward, the extension is simple to apply to  2  our proposed frailty model with change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The EM algorithm is as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' First, to deal with the unobserved  random effect, the E-step calculates the expected values of the random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The E-step  The conditional distribution on the observed data is the gamma with shape parameter Akm =  1  θk + Dkm and  rate parameter Bkm =  1  θk + �  i∈Ek Λ0(tmi) exp(βkxmi)I(τk−1 < tmi ≤ τk).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The conditional likelihood function is  obtained by replacing vkm in the likelihood function with Akm  Bkm .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The initial value of θk is 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The initial value of βk  is the estimator of the standard Cox proportional hazard model with change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The M-step  In the M-step, the estimator of the parameters that maximizes the conditional likelihood function in the E-step is  computed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For the conditional likelihood function of β and τ, the following profile likelihood function can be given  through the estimation of nonparametric hazards ˆΛ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  ˆΛ0(tmi) =  �  r:tmr≤tmi  dmr  �  j:tmi<tmj ˆvkm exp(βkxmj)I(τk−1 < tmj ≤ τk),  (5)  dmr is the number of event at tmr.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' β and τ are estimated using the following partial likelihood function,  pl1(β, τ) =  k  �  k=1  M  �  m=1  Nm  �  i=1  �  δmiβT  k xmi − dmi log  �  � �  j:ti<tj  ˆvkm exp(βT  k xjm)  �  �  �  I(τk−1 < tj ≤ τk),  (6)  where ˆvkm =  Akm  Bkm .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The estimator of θk is obtained by maximizing the conditional likelihood function on the  observed data,  cl2(θk) = −M  � 1  θk log(θk) + log  �  Γ  � 1  θk  ���  +  M  �  m=1  �� 1  θk + Dkm − 1  �  (log(Akm) − log(Bkm)) −  Akm  θkBkm  �  (7)  The candidate of change point τk is chosen from each time-to-event Ymi because the change point is considered  as the event point that may change the slope of the Cox regression in this model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Hence, for each τk, the actual  time-to-event is input.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' β and θ are then calculated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We fit all time-to-event combinations to the change point τk  and compute estimators �β of β from the equation (6) and �θ of θ from the equation (7) for each fixed change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The maximum likelihood estimator is the combination of �β, �τ, and �θ that maximizes the likelihood function (2),  where �τ is input actual times-to-events.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  3  Practical example  We demonstrate the analysis of change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We create the example dataset shown in Table 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='Table 1: Example dataset  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='Placebo Group  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='Treatment Group  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='ID  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
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+page_content='Yes  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='3  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='ST: survival time (Week)  ' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='First,' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' we introduce the analysis of a single change point and no random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The set of candidate change points  consists of actual times-to-event.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Data for the 12 candidate points of change point τ1 are (25, 30, 40, 45, 50, 60, 65, 70, 75, 80, 85, 95, 100).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The partial likelihood function with the unknown parameter β = (β1, β2)T for each τj is  pl(β, τ1) =  30  �  i=1  {(I(0 < ti ≤ τ1)β1 + I(τ1 < ti ≤ 100)β2)xi}  − log  � �  m∈R1  exp(β1xm)  �  − log  � �  m∈R2  exp(β2xm)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  (8)  R1 is the risk set for ti ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' However, when ti ≥ τ1, the data are treated as censored data, R2 is the risk set for  ti ∈ [τ1, 100].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For each change point, we calculate the estimator �β maximizing the partial likelihood function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' β1  and β2 can be computed independently.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The combination of �β and ˆτ that maximizes the partial likelihood function  is the maximum estimator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The maximum likelihood estimator was �β = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='07, −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='76) and ˆτ = 50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Data analysis  was performed using coxph function of the survival package in R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For detailed information on the algorithms, please  refer to the supplemental material.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Next, we show the analysis results of the frailty model with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The partial likelihood is  pl1(β, τ1) =  3  �  m=1  Nm  �  i=1  �  δmiβT  k xmi − dmi log  �  � �  j:ti<tj  ˆvkm exp(βT  k xjm)  �  �  �  I(τk−1 < tj ≤ τk),  (9)  and  cl2(θ1) = −3  � 1  θ1 log(θ1) + log  �  Γ  � 1  θ1  ���  +  3  �  m=1  �� 1  θ1 + D1m − 1  �  (log(A1m) − log(B1m)) −  A1m  θ1B1m  �  ,  cl2(θ2) = −3  � 1  θ2 log(θ2) + log  �  Γ  � 1  θ2  ���  +  3  �  m=1  �� 1  θ1 + D2m − 1  �  (log(A2m) − log(B2m)) −  A2m  θ2B2m  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  (10)  We input 50 to τ1, D11 = 3, D12 = 4, D13 = 0, D21 = 3, D22 = 2, and D23 = 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' From the coxph function in R,  the maximum likelihood estimators were easily calculated �β = (−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='35, −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='56), ˆτ = 80, and �θ = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='78).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Note  that ˆθ1 was not 0 but a very small value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' When survival time was biased by clusters, adjusting for the random  effect resulted in different change point estimates compared with the no random effect model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The survival curve  for each group and change points are shown in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  4  +  +  +  +  +  +  +  +  +  +  +  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='50  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='75  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00  0  25  50  75  100  Weeks  Survival probability  Group  Treatment  Placebo  τ 1=50  τ 1=80  Figure 1: Survival curves and change points of example data  + means censored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The red line and red letters are the change points of the frailty model with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The dark blue dotted  line and dark blue letters are the change points of the Cox proportional hazard with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  4  Simulation Study  We evaluated the performance of the frailty model with change points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We assume that the sample size is 500, and  the four category cluster is randomly assigned from (1, 2, 3, 4) with a probability of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='25, xmi is randomly assigned  0 or 1 with a probability of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='5, the change point is 250, the follow-up period is 600, β = (β0, β1)T = (0, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='5)T , and  the non-informative censors occur a probability of 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The number of simulations is 10,000.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We prepared three  scenarios.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Scenario 1 has no frailty.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The survival data are generated from exp(β0xim) × Exponential  �  1  300  �  up to  the change point and exp(β1xim) × Exponential  �  1  300  �  after the change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Scenario 2 has the frailty v1m and  v2m generated from Gamma(0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The survival data are generated from v1m exp(β1xim) × Exponential  �  1  300  �  up to the change point and v2m exp(β2xim) × Exponential  �  1  300  �  after the change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Scenario 3 is the case in  which the parameter of Gamma distribution in Scenario 2 changed to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The evaluation index for the simulation is  bias and mean squared error (MSE).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The bias is the average of estimator for each simulation − the true parameter  value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The MSE is the average of the squared error of the difference between the estimators and true parameter  values for each simulation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The simulation program is included in the supplemental material.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1  Simulation Results  The simulation results are shown in Table 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' When there was no random effect in Scenario 1, the estimated results  of the random effects are close to zero in the frailty model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The MSEs for �β and ˆτ1 were smaller in the frailty  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In Scenarios 2 and 3, the MSE of the change point was improved by adjusting for the variation effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The  change point bias was larger for the frailty model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  5  Table 2: Simulation results  Parameter  CP without random effect  Frailty model  Scenario 1 (θ1 = θ2 = 0)  Bias  MSE  Bias  MSE  β1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='067  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='045  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='042  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='036  β2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='071  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='057  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='022  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='052  τ1  14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='7  7958.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='8  25.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='7  7921.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='4  θ1 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='010  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='001  θ2 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='012  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='001  Scenario 2 (θ1 = θ2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1)  Bias  MSE  Bias  MSE  β1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='067  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='047  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='023  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='032  β2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='049  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='055  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='007  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='049  τ1  18.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='5  8278.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1  19.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='0  6840.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='9  θ1 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='086  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='009  θ2 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='016  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='020  Scenario 3 (θ1 = θ2 = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='2)  Bias  MSE  Bias  MSE  β1  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='067  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='047  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='020  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='030  β2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='026  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='054  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='008  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='046  τ1  22.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='6  8722.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='9  26.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='6  6346.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='9  θ1 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='179  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='036  θ2 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='039  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='057  CP: Cox proportional hazard model with change point, Frailty model: Frailty model with change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Red letter: MSE result is  superior when the frailty is taken into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  5  Clinical Trials  We show how the frailty model behaves when applied to data from two clinical trials.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='1  Re-analysis of data of a clinical trial on primary biliary cholangitis  We included data from a clinical trial on primary biliary cholangitis (PBC);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' this was a placebo-controlled randomized  trial that included 72 patients in the D-penicillamine group and 62 patients in the placebo group [13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' There is  stage (S1: no progression, S2: mild progression, S3: moderate progression, and S4: advanced progression) as the  cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In the D-penicillamine group, the number of S1 is 9, the number of S2 is 26, the number of S3 is 29, and  the number of S4 is 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In the placebo group, the number of S1 is 3, the number of S2 is 18, the number of S3 is 32,  and the number of S4 is 9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The survival curves are shown in Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The survival curves crossed near the 10-year  time point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  6  ++++  +++++++++++++ ++ ++ +++ +++ ++  +++  +  ++++++  +++  ++  + ++++  + +  +  ++ +  +++++++ +  +  +  ++++++ ++++++  +  ++  +  +  + +  +  ++++  +  + ++++  ++  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='50  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='75  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='0  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='5  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='0  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='5  10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='0  12.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='5  Years  Survival probability  Group  D−penicillamine  Placebo  τ 1=7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='58  τ 1=7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='66  Figure 2: Survival curves of cases in the PBC study  + means censored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The red line and red letters are the change points of the frailty model with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The dark blue dotted  line and dark blue letters are the change points of the Cox proportional hazard with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  For the Cox proportional hazard model with one change point, �β = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='61, −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='54)T and τ1 = 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='58.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For the  frailty model with one change point, �β = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='73, −0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='19)T , τ1 = 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='66, and �θ = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='66, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='70)T .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The data before the  change point had a small random effect, but after the change point, the random effect was large and the value of  ˆβ2 changed depending on the change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The change point did not change markedly, but it shifted back a bit to  a point in time by taking into account the random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='2  Re-analysis of data of a clinical trial on malignant glioma  We included data from a clinical trial on malignant glioma (MG);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' the placebo-controlled randomized trial contained  110 patients in the group of patients treated with chemotherapeutic agents incorporated into biodegradable polymers  (polymer) and 112 patients in the placebo group [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' There is tumor histopathology at implementation (path)  (P1: glioblastoma, P2: anaplastic astrocytoma, P3: oligodendroglioma, P4: other) as the cluster.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For the polymer  group, the number of P1 is 76, the number of P2 is 14, the number of P3 is 15, and the number of P4 is 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For the  placebo group, the number of P1 is 73, the number of P2 is 16, the number of P3 is 20, and the number of P4 is 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  The survival curves are shown in Figure 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  7  +  ++  ++++  +  +  ++  ++  +  +  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='25  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='50  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='75  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='00  0  50  100  150  200  Weeks  Survival probability  Group  Polymer  Placebo  τ 1=32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='57  τ 1=30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='14  Figure 3: Survival curves of cases in the MG study  + means censored.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The red line and red letters are the change points of the frailty model with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The dark blue dotted  line and dark blue letters are the change points of the Cox proportional hazard with one change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  For the Cox proportional hazard model with one change point, �β = (−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='44, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='18)T and τ1 = 30.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='14.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' For the  frailty model with one change point, �β = (−0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='45, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='18)T , τ1 = 32.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='57, and �θ = (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='40, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='08)T .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Because the random  effects are small, the estimators remained almost unchanged.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  6  Discussion  We propose the novel frailty model with change points to adjust the heterogeneity between clusters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' There are  clusters of primary diseases, clinical facilities, severity of interest disease, and so on.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our proposed model can be  easily analyzed using the coxph function and frailty option.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We confirmed that the accuracy of the estimation is  increased by considering heterogeneity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our simulation studies showed that the accuracy of change point estimation  deteriorated because of heterogeneity, and the accuracy of estimation was improved using the frailty model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We  included the R program code of analyses for the practical example, simulation, and two clinical trials in the  Supplementary Materials.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' From the simulation study, we confirmed that adding frailty in all estimators for all  scenarios resulted in smaller MSEs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Increasing the size of the random effect confirmed that the estimated change  point of the Cox proportional hazard model with the change point model has a larger MSE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' This suggests that the  random effect affects the estimation accuracy of the change point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In the frailty model with the change point, the  MSE of the change point estimator became smaller as the random effect increased.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The accuracy of data estimation  increased as the random effects were adjusted.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The bias of the average estimated change points is larger for the  frailty model, but the MSE is very large that we considered the difference in bias between the models to be within  the margin of error.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In the re-analysis of data from the PBC trial, the random effect size was more significant in the  interval where the survival function is crossed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' We confirmed that the estimates of the parameters of the regression  coefficients change when the random effect is taken into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In the re-analysis of data from the MG trial, the  estimation results did not differ regardless of the presence or absence of frailty because of the small variate effects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Thus, this analysis confirmed that our model does not deviate from the estimation results of the Cox proportional  hazard model with a change point when the variate effects are small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' In conclusion, we confirmed that the frailty  model with change points has higher accuracy than the model without the random effect.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our proposed model  can be easily analyzed using the existing R package.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Our proposed model is useful when heterogeneity needs to  be taken into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' Additionally, the absence of heterogeneity did not affect the estimation of the regression  coefficient parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  Author Contributions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' MK analyzed the example data, simulation datasets, and two clinical trial data and  wrote the manuscript.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' OS proposed the research theme, reviewed and corrected the manuscript.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  8  Acknowledgements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content='  MK would like to thank Associate Professor Hisashi Noma for his encouragement and  helpful suggestions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
+page_content=' The authors would like to thank PhD student Ryoto Ozaki for his helpful comments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9E3T4oBgHgl3EQfNwnN/content/2301.04387v1.pdf'}
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diff --git a/u9FPT4oBgHgl3EQfNzRd/content/tmp_files/2301.13031v1.pdf.txt b/u9FPT4oBgHgl3EQfNzRd/content/tmp_files/2301.13031v1.pdf.txt
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+BSSAD: Towards A Novel Bayesian State-Space
+Approach for Anomaly Detection in Multivariate
+Time Series
+Usman Anjum
+University of Cincinnati
+Cincinnati, OH, USA
+anjumun@ucmail.uc.edu
+Samuel Lin
+University of Arkansas
+Fayetteville, Arkansas, USA
+smlin@uark.edu
+Jusin Zhan
+University of Cincinnati
+Cincinnati, OH, USA
+zhanjt@ucmail.uc.edu
+Abstract—Detecting anomalies in multivariate time series
+(MTS) data plays an important role in many domains. The
+abnormal values could indicate events, medical abnormalities,
+cyber-attacks, or faulty devices which if left undetected could
+lead to significant loss of resources, capital, or human lives.
+In this paper, we propose a novel and innovative approach to
+anomaly detection called Bayesian State-Space Anomaly Detection
+(BSSAD). The BSSAD consists of two modules: the neural network
+module and the Bayesian state-space module. The design of
+our approach combines the strength of Bayesian state-space
+algorithms in predicting the next state and the effectiveness of
+recurrent neural networks and autoencoders at understanding
+the relationship between the data to achieve high accuracy
+in detecting anomalies. The modular design of our approach
+allows flexibility in implementation with the option of changing
+the parameters of the Bayesian state-space models or swap-
+ping neural network algorithms to achieve different levels of
+performance. In particular, we focus on using Bayesian state-
+space models of particle filters and ensemble Kalman filters.
+We conducted extensive experiments on five different datasets.
+The experimental results show the superior performance of our
+model over baselines, achieving an F1-score greater than 0.95.
+In addition, we also propose using a metric called Matthew
+Correlation Coefficient (MCC) to obtain more comprehensive
+information about the accuracy of anomaly detection.
+Index Terms—Bayesian state-space models, Particle filters,
+Ensemble Kalman filters, Anomaly detection
+I. INTRODUCTION
+Anomaly detection in multivariate time series (MTS), also
+referred to as outlier or novelty detection, is the task of de-
+tecting data that deviates significantly from expected behavior.
+A multivariate time series consists of more than one time-
+dependent variable. Each variable depends not only on its
+past values but also has a dependency on other variables. In
+the medical domain or cyber-physical system, these variables
+could be sensors measurement like temperature, pressure, etc.
+Anomaly detection has applications in many domains. For
+example, in event detection [1], in the financial domain to
+identify fraud, in cyber-security to identify cyber-attacks, for
+identifying medical risks, or for fault detection in cyber-
+physical systems [2].
+Detecting anomalous behavior in multivariate time series
+has been an active area of research for a long time [3], [4].
+Most of the previous works have focused on presenting mul-
+tivariate time series as a collection of single time dependant
+variables without focusing on the dependencies between the
+variables [5], [6]. These works have been classified as residual-
+based anomaly detection [7]. In residual-based anomaly de-
+tection, recurrent neural networks or autoencoders are usually
+implemented to predict future values [8]. Then the predicted
+and the actual values are compared to calculate a residual error.
+Any error that exceeds a threshold value greater than the actual
+value is classified as an anomaly. Recently, there has been a
+focus on designing methods that consider multivariate time
+series as a whole by finding relationships along the temporal
+domain and between the features. The results from these
+methods have been highly promising [7], [9]. These methods
+have been referred to as density-based algorithms and have
+been able to achieve higher accuracy compared to residual-
+based algorithms in detecting anomalies.
+Density-based algorithms detect anomalies in multivariate
+time series data using Bayesian Theory. In Bayesian theory, the
+next state of a system is estimated by constructing the posterior
+probability density function of the data from a prior distribu-
+tion. It is assumed that normal data is sampled from a posterior
+density function different from the one that anomalous data is
+sampled from. Hence, any data point that does not follow the
+same distribution or deviates significantly from the distribution
+followed by the normal data will be flagged as an anomaly.
+The most common state estimation techniques include Kalman
+filters and its variants [10], Sequential Monte Carlo (SMC) and
+Markov Chain Monte Carlo (MCMC) methods [11], [12].
+Implementing Bayesian state-space algorithms for anomaly
+detection in multivariate time series has significant obstacles.
+One obstacle is that to properly estimate the state, key knowl-
+edge about the mathematical relationship between the features
+(sensors) and their values along the time domain is required.
+Most of the previous works on state estimation have been built
+using physics equations [13]. But that may not always be the
+case and definite mathematical models between the variables
+may not be available. Another key obstacle is that there is no
+information about the posterior distribution.
+To deal with these obstacles, we propose a novel and
+arXiv:2301.13031v1  [cs.LG]  30 Jan 2023
+
+innovative density-based anomaly detection algorithm called
+Bayesian State-Space Anomaly Detection (BSSAD). Our
+method consists of two main modules: the neural network
+module (NNM) and the Bayesian state-space module (BSSM).
+The NNM is based on recurrent neural networks and autoen-
+coders. The BSSM is implemented using Bayesian state-space
+estimation techniques of ensemble Kalman filters (EnKF) and
+particle filters (PF).
+Our method is motivated by the density-based algorithm
+presented in [7]. To develop mathematical relationships be-
+tween the variables, we use a combination of recurrent neural
+networks, more specifically long short-term memory (LSTM)
+[14], and autoencoders (AE). LSTM and AE have been widely
+used for anomaly detection [15]–[17]. The Bayesian state-
+space techniques estimate the posterior distribution using a
+Monte Carlo (MC) method. In MC methods, the posterior
+distribution is represented as a set of random samples from
+a known distribution. As the number of samples increases,
+the true posterior probability density function (pdf) can be
+estimated. Both EnKF and PF are types of MC methods.
+In contrast to the algorithm in [7], which implemented
+a variant of the Kalman filter called an unscented Kalman
+filter (UKF) [18], [19] to detect anomalies, our work im-
+plements ensemble Kalman filters (EnKF) and particle filters
+(PF) for constructing the posterior distribution and detecting
+the anomalies. UKF, EnKF, and PF can efficiently handle
+continuous, multivariate, and non-linear systems. PF have
+an added advantage of being able to handle multimodal,
+extremely non-Gaussian noise, and occlusions problems [10].
+Previous research has shown that both EnKF [13], [20] and
+PF [21] have been shown to have better accuracy in estimating
+the next state when compared to UKF.
+Once the posterior distribution has been obtained, we calcu-
+late the Mahalanobis distance to find the distance between the
+current state and the predicted distribution. Any value whose
+distance exceeds a threshold is considered an anomaly.
+The contribution of our work is as follows:
+Formulation & Algorithm: We propose the novel Bayesian
+State-Space Anomaly Detection (BSSAD) 1 model that utilizes
+state-space algorithms and neural networks to detect anoma-
+lies. We implement our model using Ensemble Kalman filters
+(EnKF) and particle filters (PF). To the best of our knowledge,
+no other works have focused on using EnKF and PF for
+anomaly detection in multivariate times series data.
+Accuracy: We applied our model to multiple data sets. The
+results of our analysis showed that our model can achieve
+a F1-score. In addition, we propose to use the Matthews
+correlation coefficient (MCC) to measure the accuracy of
+anomaly detection as an alternative to the F1-score. MCC has
+been considered as a better metric than F1-score in binary
+classification tasks [22].
+Generality: The modular design of our model allows it to
+be highly flexible. Different parameters can be changed and
+1https://github.com/BSSAD2022/BSSAD
+algorithms can be easily swapped out so that our method can
+be applied to different data types and across multiple domains.
+The paper is organized as follows: In Section II we provide
+a review of related literature. In Section III, we provide an
+overview of key concepts that are necessary for building our
+model. In Section IV, we present our model. In Section V
+we present our experiments and observations and finally, in
+Section VI we conclude.
+II. LITERATURE REVIEW
+There are many different anomaly detection algorithms
+available in the literature. Typically, anomaly detection al-
+gorithms are classified as supervised or unsupervised. Some
+researchers have proposed other classification techniques for
+anomaly detection methods. In [7], anomaly detection al-
+gorithms were classified as residual-error based and density
+based. Residual-error based methods predict the next value and
+find the difference between the predicted and actual values.
+Density-based methods find the distribution of the data and
+data is flagged as an anomaly if it is not part of the distribution.
+In [23], the anomaly detection algorithms were classified
+as statistics-based, classification-based, vocabulary-based, and
+reconstruction-based. Statistics-based methods are similar in
+definition to density-based algorithms. The data is assumed
+to follow a normal distribution and a variable is classified as
+normal if it is within the 3σ range. Classification is usually
+done using labeled data with high accuracy. However, labeled
+data is hard to obtain, thus the use of unlabeled methods
+is more common. Vocabulary-based methods aim to find
+patterns in time-series data and data deviating from these
+patterns is classified as an anomaly. Finally, reconstruction-
+based methods are similar to residual-error based methods.
+Most work found in the literature aims at using recon-
+struction or residual-error based methods. One of the most
+common methods that have served as a benchmark for many
+other methods is the Isolation Forest [5]. The isolation forest
+is based on a tree-based architecture to identify anomalies but
+it is not made for multivariate time-series data.
+Neural networks, more specifically recurrent neural net-
+works (RNN) and autoencoders or a combination of both,
+have recently become very popular as a method to detect
+anomalies. An extensive review of the application of deep
+learning techniques in anomaly detection can be found in [2],
+[3], and [8]. Recently, transformers have also been proposed
+for detecting anomalies [24]. They renovate transformers for
+anomaly detection by adding an anomaly-attention mecha-
+nism.
+Most works have focused on implementing long-short term
+memory (LSTM), a type of RNN, for reconstruction [25], [26].
+One example of using autoencoders for anomaly detection
+was USAD [6], [27], [28]. Methods combining both LSTM
+and autoencoders to detect anomalies include [15]–[17], [29]
+and [30]. Generative adversarial networks (GAN) have also
+been proposed for anomaly detection [31], [32]. All these
+methods are classified as residual-error or reconstruction-based
+anomaly detection.
+
+Fig. 1. Anomalies in sensor data
+Algorithms that can be classified as density or statistical-
+based anomaly detection include [33] and Omnianomaly [34].
+These methods use generative models to predict the distribu-
+tion of the data.
+Bayesian state-space methods are also examples of density-
+based algorithms. Even though these methods have mainly
+been applied for next state estimation [10], [21], [35], there
+have been some works that have applied Bayesian state-space
+estimation for anomaly detection. However, most of the work
+has been restricted to fault detection [36] or anomaly detection
+in videos [37] and [38]. Ensemble Kalman filters have not been
+used for anomaly detection and have only been implemented
+for state estimation in weather or medical domains [20].
+In [9], hierarchical variational autoencoders combined with
+Markov Chain Monte Carlo (MCMC) is used to learn temporal
+and inter-sensor correlation. A data point is flagged as an
+anomaly if it does not follow the temporal or inter-sensor
+correlation. A relevant work that has implemented Bayesian
+state-space algorithms was called Neural System Identification
+and Bayesian Filtering [7]. In [7] the AE and LSTM methods
+are improved further by adding a unscented Kalman Transform
+(UKF). UKF is able to learn the temporal and inter-sensor
+relationship and is able to approximate the distribution of the
+next state.
+III. PRELIMINARIES
+Figure 1 shows how anomalies would manifest in real-world
+data. The anomalies would represent deviations from past
+patterns not only along the time-domain but also between dif-
+ferent sensor values. In this section, we describe the Bayesian
+state-space model which forms the basis for our BSSM and
+can be used to find the relationships between the past values
+of the features and between different features. In particular, we
+present the theory behind EnKF and PF which we implement
+in our model.
+In a Standard multivariate times series data can be rep-
+resented as X = (x0, ..., xT ), xϵRMwhere x are M features
+(also referred to as sensors, or variables), that can produce
+continuous or discrete values (when x is discrete, it is referred
+to as control input in the literature) and T is the time interval
+over which the sensor values were obtained. A state-space
+evolution is defined by two equations:
+zt = Ft(zt−1, qt−1)
+(1)
+xt = Ht(zt, rt)
+(2)
+Equation (1) is the state transition equation [10]. In the
+equation, zt and zt−1 are the hidden state variables at time
+t and t−1 respectively (e.g. actual value of a sensor), qt−1 is
+an i.i.d. process noise, and Ft is the state transition function
+that maps the previous state (zt−1) to the current state (zt).
+Equation (2) is the measurement equation [10]. In the
+equation xt is the observed measurement at time t, zt is
+the hidden measurement (state) of the sensor, rt is the i.i.d.
+measurement noise and Ht is the measurement function that
+maps the hidden states (zt) to the observed measurements (zt).
+The objective is to estimate the state zt given the state
+x1:t = xi, i = 1, ...., t up to time T. From a Bayesian perspec-
+tive, the objective is to construct the pdf p(zt|x1:t). The pdf
+is constructed recursively in two stages: prediction and update
+[21] represented by (1) and (2), respectively. It is assumed that
+the initial state is the pdf p(z0|x0) ≡ p(z0). In the prediction
+stage, the system model in (1) is used to obtain the prior pdf
+of the state at time t. Assuming that the prior pdf is given as
+p(zt−1|x1:t−1), then the prediction equation is:
+p(zt|x1:t−1) =
+�
+p(zt|zt−1)p(zt−1|x1:t−1)dzt−1
+(3)
+It should be noted that p(zt|zt−1) is equivalent to the state
+transition equation from (1).
+In the update stage, zt is used to modify the prior pdf to
+obtain the required posterior pdf. The update stage is then
+defined as:
+p(zt|x1:t) = p(xt|zt)p(zt|x1:t−1)
+p(xt|x1:t−1)
+(4)
+where p(xt|x1:t−1)
+=
+�
+p(xt|zt)p(zt|x1:t−1)dzt. In the
+above equation p(xt|zt) is defined from the measurement
+model in (2).
+The solution to these equations is obtained recursively but
+cannot be determined analytically. The optimum solution can
+only be obtained in certain cases. For example, the Kalman
+filter assumes that the posterior distribution and the noise
+are Gaussian and Ft and Ht are linear. However, in most
+cases, these assumptions are not true. In such cases, only
+sub-optimal solutions exist. Extended Kalman filter (EKF),
+Unscented Kalman filter (UKF) [18], [19], Ensemble Kalman
+filter (EnKF) [39], [40] and Particle filters (PF) [21] are
+examples that provide approximate solution to the posterior
+pdf [10], [21], [41]. In sub-optimal methods, the objective is
+to generate samples from a known prior distribution, propagate
+these samples using (1) and (2) and obtain the posterior
+distribution from the result. These samples are referred to as
+sigma points in UKF and EnKF and particles in PF. In the
+following sections, we will describe in detail how the posterior
+distribution is estimated using EnKF and PF.
+
+600
+500
+400
+300
+200
+100
+0
+1
+20001
+40001
+60001
+80001
+100001
+120001
+140001
+sensor33
+sensor34
+sensor35
+AnomalyA. Ensemble Kalman Filter
+EnKF are non-linear approximations to the state estimation
+problem. The EnKF is very similar to UKF [10] but different
+in some ways. In UKF, a set of weighted sigma points
+are generated deterministically and are passed through the
+state transition and measurement functions. The mean and
+covariance of the sigma points are an approximate measure of
+the posterior pdf’s state mean and covariance. However, EnKF
+relies on Monte Carlo simulation to generate a large number
+of sigma points from a known distribution. The generated
+sigma points are then propagated using the state transition
+and measurement function in a similar way to UKF. Another
+difference is that unlike UKF, where the sigma points are
+generated at each iteration, in EnKF the sigma points are
+randomly generated based on a distribution only in the initial
+stage, and are then propagated at each iteration.
+The first step in designing the EnKF is the initialization
+stage. In the initial stage N sigma points (χ) are generated
+using a known mean and variance. Like any Bayesian state-
+space algorithm, there is a predict stage and an update stage.
+The implementation of the EnKF varies in different literature
+[10]. The predict stage consists of passing the N sigma points
+(χ) through state transition function (Ft) to obtain χf. The
+predict stage is implemented using the following equation:
+χf = Ft(χt−1) + Nq
+(5)
+Nq is the state transition noise matrix.
+As mentioned in Section III, the purpose of the update
+stage is to update the sigma points and obtain the posterior
+mean and covariance. The posterior mean and covariance
+are the estimates for the posterior distribution. The updated
+sigma points and the posterior mean and covariance become
+the prior state, mean and covariance for the next iteration.
+There are multiple ways of implementing the update state and
+there is no clear consensus on which way to use [10]. We
+propose to implement the update state using the following set
+of equations, which gave us the best performance:
+χh = Ht(χf) + Nr
+µz = 1
+N
+N
+�
+1
+χh
+Pzz = 1
+N
+N
+�
+1
+[χh − µz][χh − µz]T
+Pxz =
+1
+N − 1
+N
+�
+1
+[χf − µt−1][χh − µz]T
+K = PzzP −1
+xz
+χt = χf + K[xt − χh + er]
+ˆµt = 1
+N
+N
+�
+1
+χt
+ˆPt = Pt−1 − KPzzKT
+(6)
+The sigma points are first passed through the measurement
+function to obtain the hidden state χh. Using χh the mean µz
+is calculated. Next, we calculate Pzz and Pxz which are the
+auto-correlation between χh and the cross-correlation between
+χh and χf, respectively. Pzz and Pxz are used to calculate
+the Kalman Gain, K. In our equations, we chose to change
+the method of calculating Pxz and use µt−1 instead of xt−1
+[10]. The K is a key parameter in the EnKF framework. It is
+the weight given to the current state estimate and the actual
+state. Its purpose is to automatically tune the filter to estimate
+the next state as accurately as possible. The sigma points
+(χt) are updated using the Kalman gain (K) which serves as
+input sigma points for the next stage. Nr is the measurement
+noise matrix and er is perturbation added to the sigma points.
+Finally, using the updated sigma points χt, the posterior pdf
+can be estimated as state mean ˆµt and covariance ˆPt.
+B. Particle Filter
+Particle filters belong to a class of Monte Carlo (MC) meth-
+ods called sequential MC (SMC) filters [21]. They are based
+on the sequential importance sampling (SIS) algorithm. Other
+SMC algorithms include bootstrap filtering, condensation al-
+gorithm, interacting particle approximations, and survival of
+the fittest [21]. Like EnKF, SMC algorithms also generate
+sigma points (which are called particles) sampled from a
+known probability distribution. However, unlike EnKF each
+particle is assigned a weight. The posterior distribution can
+then be estimated from the weighted particles. As the number
+of particles reaches infinity, a true representation of posterior
+pdf can be obtained.
+A generic SIS particle filter consists of the following steps:
+• Generate samples called particles from a known distribu-
+tion.
+• Assign each particle a weight
+• Resample the particles based on the updated weights.
+• Calculate the state and measurement mean and covariance
+using the particles and their weights.
+The posterior distribution is estimated using the equation:
+p(zt|x1:t) ≈
+Ns
+�
+i=1
+ωi
+tδ(zt − xi
+t)
+(7)
+where
+ωi
+t ∝ ωi
+t−1
+p(xt|xi
+t)p(xi
+t|xi
+t−1)
+q(xi
+t|xi
+t−1, xt)
+(8)
+Here, δ(�) is an indicator function, xi
+t are the particles
+that are sampled from a known distribution q(�) (also called
+importance density). Ns are the number of particles sampled
+from q(�). xt is the input data, zt is the hidden state and wt
+i
+is the ith weight at time t and �
+i ωi
+t = 1. The weights are
+chosen using the principal of importance sampling and the
+details of the derivation of the equations can be found in [21],
+[41].
+A common problem with particle filters is particle degener-
+acy. Particle degeneracy happens when after a few iterations,
+
+Fig. 2. BSSAD Model
+all but one particle will have negligible weight. Once that
+happens the filter will be unable to estimate the next state. A
+measure for particle degeneracy is the effective sample size,
+Neff. However, Neff cannot be measured directly and only
+an estimate can be calculated [21]. The equation for Neff is:
+ˆNeff =
+1
+�Ns
+i=1(wi
+t)2
+(9)
+There are two main ways of reducing particle degeneracy.
+One is through good choice of importance density, and the
+other is through resampling [21]. The importance density can
+be chosen using another state-space estimation method like
+Kalman filters, unscented transform, or using a Gaussian esti-
+mate. For our model, we consider using a Gaussian estimate
+for importance density.
+The second method of resampling may be computationally
+expensive. Hence, a common technique is to resample when-
+ever a significant degeneracy is observed, i.e. when Neff
+falls below a threshold NT . The concept of resampling is
+to remove all particles with small weights and focus more
+on particles with large weights. Some of the resampling
+methods found in the literature are multinomial, stratified,
+residual, and systematic resampling [10]. In this paper, we
+use systemic resampling schemes as it is the most popular of
+the resampling algorithms and performs the best amongst all
+the other resampling methods [10], [21].
+A variation on the SIS particle filter is the sampling im-
+portance resampling (SIR) filter. The SIR filter is an MC
+method that can be applied to recursive Bayesian state-space
+problems. The SIR filter incorporates the state transition and
+measurement functions to propagate and update the parti-
+cles. The advantage of the SIR filter is that the importance
+weights are easy to calculate and importance density can
+be easily sampled. In an SIR filter, the importance density
+q(zt|xi
+t−1, x1:k) = p(zt|xi
+t−1) and the particles are resam-
+pled at each step. Consequently, the weights are given by
+wi
+t ∝ wi
+t−1p(xt|xi
+t) where wi
+t−1 =
+1
+Ns .
+IV. METHODOLOGY
+The overall methodology can be found in Figure 2. Our
+method consists of two main modules: the neural network
+module (NNM) and the Bayesian state-space module (BSSM).
+The basis for BSSM is to use state-space methods to predict
+the mean and covariance of the distribution of the next state.
+If the sensor value deviates significantly from the predicted
+distribution, then it is an anomaly. The first step in the anomaly
+detection model is to design the state-space model. The focus
+of this paper is to use EnKF and SIR-PF to estimate the
+posterior distribution by estimating the state mean (ˆµt) and
+the state covariance matrix ( ˆ
+Pt). In order to design EnKF and
+PF, there are four main parameters that must be determined:
+• state transition equation F that maps the previous states
+to the current state
+• process noise q
+• measurement equation H that maps the state to the hidden
+(measurement) state
+• measurement noise r
+Since, there are no predefined set of mathematical equations,
+in this paper, we follow the model presented in [7] to estimate
+F, q, H, and r. These parameters were estimated using recur-
+rent neural networks. Specifically, F is estimated using long
+short-term memory (LSTM) [14]. The measurement equation
+H is estimated from an autoencoder which maps the input to
+a lower latent dimension. Both LSTM and autoencoders by
+themselves have been used for anomaly detection [4], [8]. By
+adding a spate space algorithm that leverages autoencoders and
+LSTMs, the accuracy of anomaly detection can be significantly
+improved.
+In the upcoming sections, we will describe the implemen-
+tation details of our modules.
+A. Neural Network Module (NNM)
+The NNM consists of two subnets which are referred to as F
+and H. Each of these subnets have their own parameters. The
+subnet F takes in state variables to provide times-series esti-
+mates for the state transitions. It combines the input from zt−1
+and xt−τ:t−1, where τ is the window size, to obtain the next
+state estimate zt. It is defined as F : (zt−1, xt−τ:t−1)ϵRM ′ →
+ztϵRM ′. In the autoencoder, the encoder H is defined as
+H : xtϵRτ×M → ztϵRτ×M ′ where M are the number of
+sensors that are mapped onto a hidden dimension M ′. This
+is equivalent to the measurement function. Consequently, the
+decoder maps the hidden state zt back to the state variable xt
+and is defined as H−1 : ztϵRW ×M ′ → ˆxtϵRW ×M.
+The neural network is trained using data with normal values,
+X(n). The normal data is first divided into training(X(n)
+train)
+and validation set (X(n)
+val). X(n)
+train is used to train the NNM.
+Following [7], the loss function of the neural network is
+defined as:
+L =
+T
+�
+t=τ
+α1||xt−1 − ˆxt−1||2
+2 + α2||xt − ˆxt||2
+2 + α3||zt − zt−1||2
+2
+(10)
+where ˆxt and ˆxt−1 are the reconstruction data and zt and
+zt−1 are the hidden states for t and t − 1 respectively. In
+the equation, the first two terms are the reconstruction and
+prediction errors for sensor values. The third factor is for
+smoothing the consecutive hidden states and ensuring that the
+hidden states are close to each other. The model is trained
+using the ADAM [42].
+
+qt
+rt
+(K /wl)
+Zt
+xt-1
+F
+-H
+BSSM
+Ut, I
+H
+Zt-1
+NNM :TABLE I
+HYPERPARAMETERS
+Hyperparameter
+Dataset
+Value or Range
+w1
+ALL
+0.45
+w2
+ALL
+0.45
+w3
+ALL
+0.45
+τ
+PUMP
+5
+τ
+WADI
+12
+τ
+SWAT
+12
+τ
+HTTP
+12
+τ
+ASD
+12
+NUM. Dimensions For zt
+PUMP
+[1, 120]
+NUM. Dimensions For zt
+WADI
+[1, 200]
+NUM. Dimensions For zt
+SWAT
+[1, 75]
+NUM. Dimensions For zt
+HTTP
+[1, 200]
+NUM. Dimensions For zt
+ASD
+[1, 200]
+NUM. Hidden Layers for H
+ALL
+[1, 3]
+NUM. Dense Layers for F
+ALL
+[1, 3]
+NUM. LSTM Layers for F
+ALL
+[1, 3]
+NUM Dimensions in Hidden Layers
+ALL
+[32, 256]
+Training Epochs
+ALL
+100
+In addition, process and measurement noise are calculated
+from the neural network. The noise is calculated using X(n)
+val.
+The process noise q is found using the following equation:
+qt = H(xt) − F(H(xt−1), xt−τ:t−1)
+(11)
+Similarly, the measurement noise is found using the equa-
+tion:
+rt = xt − H−1(H(xt))
+(12)
+Using qt and rt, the process covariance matrix Q and
+measurement noise covariance matrix R can be found, which
+we use later in our state estimation equations.
+For training the neural network, we followed the guidelines
+provided in [7]. To guide the hyperparamter tuning of the
+model, we used the uniform negative sampling algorithm to
+generate anomalous values. Next, a randomized grid search
+algorithm was used to fine-tune the hyperparameters and the
+model with the best anomaly detection performance. The
+hyperparameter summary is given in Table IV-A.
+B. Anomaly Detection using Bayesian State-Space Module
+(BSSM)
+In this section, we explain the implementation of the BSSM
+and designing of the state-space method. The BSSM is applied
+to the data set that contains both normal and anomalous
+data (denoted X(a)). The state-space algorithm calculates the
+posterior probability p(zt|xt−τ:t−1) and determines a value xt
+to be an anomaly if it is not part of the posterior distribution.
+Using the state transition function and measurement function
+from the NNM, the state-space equations are:
+zt = F(zt−1, xt−τ:t−1) + qt
+(13)
+xt = H−1(zt) + rt
+(14)
+It is assumed that both qt and rt are sampled from a Gaus-
+sian distribution. Hence, qt ∽ N(z0, Q) and rt ∽ N(0, R)
+where Q is the process noise covariance matrix and R is
+the measurement noise covariance matrix, ˆz0 = H(x0) and
+P0 = αI, where I is the identity matrix. α is a factor for
+scaling the covariance matrix.
+1) Ensemble Kalman Filter Design: In this section we
+explain the implementation detail of EnKF using (5) and (6).
+The problem with implementing EnKF from the equations is
+that the filter did not converge. We implementing EnKF using
+equations obtained from NNM by sampling the sigma points
+from a normal distribution that is an estimation of the hidden
+state. We call our proposed algorithm Neural Network EnKF
+(NN-EnKF) (Algorithm 1).
+Algorithm 1: Neural Network Ensemble Kalman Filter
+(NN-EnKF)
+Data: Input multivariate time series data, XϵRM×T ,
+M sensors and T time values
+Result: Estimated states, ˆµϵR1×M, ˆPϵRM×M
+Initialization: χ ∽ N(ˆz0, P0);
+for i = 1 : T do
+/* Predict using (5)
+*/
+χh = F(χt−1, xt−τ:t−1);
+/* Update using (6)
+*/
+χf = H−1(χh);
+Find Pzz, Pxz&K;
+Sample er ∽ N(0, R);
+Update Sigma Points: χt ← χf + K[xt − χh + er];
+Estimate state: ˆµt ← 1
+N
+�N
+i=1 χt;
+Estimate state covariance ˆPt ← Pt−1 − KPzzKT
+end
+Using (5) and (6), the updated equations are;
+χh = F(χt−1, xt−τ:t−1)
+χf = H−1(χh)
+(15)
+Where the sigma points χt are used to represent the
+hidden state and is sampled from a normal distribution,
+χt ∽ N(ˆz0, P0), χϵRN where N are the number of sigma
+points. χh is the result after the state transition function is
+applied to χt and χf are the sigma points transformed back
+from the hidden state.
+For initialization, to enable the filter to converge, α was
+set at a high value (which was 100). It was observed that the
+state transition and process noise are set to 0 as they did not
+seem to make any contributions to the accuracy of the state
+estimation. Instead, we sampled the error perturbation from a
+multivariate normal distribution with mean 0 and covariance
+R - er ∽ N(0, R), erϵRN where N are the number of sigma
+points.
+
+Using Pxx and Pxz, K can be calculated which is used to
+update the sigma points. The updated sigma points become the
+input for the next state. The mean and variance of the sigma
+points become the state estimate.
+2) Particle Filter Design: The next novel algorithm we use
+in BSSM is the modified version of SIR-PF called Neural
+Network SIR PF (NN-SIR). The first step is choosing the
+importance density. We choose a Gaussian distribution as the
+importance density. The particles are sampled from a normal
+distribution, xi
+t ∽ N(ˆz0, P0), i = 1 : Ns where Ns are number
+of particles and P0 is found with a very small α. The weights
+are initialized as wi =
+1
+Ns where i = 1, ...Ns. The state mean
+and covariance can be estimated using the following equations:
+Xh = F(Xt−1, xt−τ:t−1) + qt
+Xf = H−1(Xh) + rt
+(16)
+In the equation Xt−1 = xi
+t−1, i = 1, ...Ns, Xh is the result
+after the state transition function is applied to Xt−1 and Xf
+are the sigma points transformed back from the hidden state.
+The state transition noise is sampled from a normal distri-
+bution defined by qt ∽ N(ˆz0, Q). The process noise is also
+sampled from a normal distribution defined by rt ∽ N(0, R).
+At each iteration, the weights are updated by finding the
+squared error distance between Xh and xt. To measure the
+distance, we use the radial basis kernel function (RBF). The
+RBF is defined as:
+rbf(xt, Xf) = exp(||xt − Xf||2
+2σ2
+)
+(17)
+where σ is a scaling number. The weights are then updated
+by Wu = W ∗ rbf(xt, Xf) where W = wi
+t....wNs
+t . The
+updated weights are like probabilities that determine how sig-
+nificant each particle is in relation to the data. The state mean
+and state covariance can then be determined from Xh and
+Wu. To avoid particle degeneracy, the particles are resampled
+using systematic resampling as described in Section III-B.
+Systematic resampling gave the best performance for PF and
+we chose this resampling method. We set Nt = 0.1. To further
+avoid degeneracy, Nrs (we used Nrs = 1) percent of the
+particles are resampled from the prior Gaussian distribution.
+The resampled particles are the input to the next state. The
+algorithm for the NN-SIR filter is given in Algorithm 2.
+3) Anomaly Detection: Let the predicted state mean and
+covariance be represented as ˆµt and ˆPt. The anomaly score
+can be found as the distance between the actual state and the
+predicted mean and covariance. To the find the distance, we
+use the Mahalanobis distance [10]. The Mahalanobis distance
+is defined as:
+m =
+�
+(xt − ˆµt)T ˆP −1
+t
+(xt − ˆµt)
+(18)
+A larger m, indicates a higher likelihood for xt to be an
+anomaly. The anomaly threshold can be adaptive based on
+previous values or a hard threshold can be set or using the
+Algorithm 2: Neural Network SIR Particle Filter (NN-
+SIR)
+Data: Input multivariate time series data, XϵRM×T ,
+M sensors and T time values
+Result: Estimated states, ˆµϵR1×M, ˆPϵRM×M
+Initialization: Sample xi
+t ∽ N(ˆz0, P0), i = 1 : Ns and
+assign weight wi
+t =
+1
+Ns for i = 1 : Ns;
+for t = 1 : T do
+for i = 1 : Ns do
+/* propagate weights
+*/
+xi
+t = H−1((F(xi
+t−1xt−τ:t−1) + qt) + rt;
+normalize weights: wi
+t =
+wi
+t
+�Ns
+i=1 wi
+t ;
+end
+/* Update Particles
+*/
+if ˆNeff < NT then
+{xi
+t, wi
+t}Ns
+i
+= RESAMPLE({xi
+t, wi
+t}Ns
+i )
+end
+Resample xi
+t ∽ N(ˆz0, P0), i = 1 : Ns ∗ Nrs
+Estimate state: ˆµt ←
+1
+Ns
+�N
+i=1 wi
+txi
+t ;
+Estimate covariance:
+ˆPt ←
+1
+�Ns
+i=1 wi
+t
+�Ns
+i=1 wi
+t(xi
+t − ˆµt)
+end
+algorithm defined in [31]. A value is considered to be an
+anomaly if its Mahalanobis is above a specific threshold.
+The complete algorithm for our model Bayesian State-Space
+Anomaly Detection (BSSAD) is given in Algorithm 3
+Algorithm 3: Bayesian State-Space Anomaly Detec-
+tion (BSSAD)
+Data: Input multivariate time series data, XϵRM×T ,
+M sensors and T time values
+Result: Anomaly Scores (m)
+Initialization:
+Split X into normal only (X(n)) and normal &
+anomalous data (X(a));
+Split X(n) into X(n)
+train and X(n)
+val;
+Train neural network using X(n)
+train;
+Estimate noise on X(n)
+val using (11) and (12);
+Divide X(a) into window size τ;
+for t = 1 : T
+τ do
+Estimate ˆµt and ˆPt for X(a) using Algorithm 1 or
+2;
+Calculate anomaly score (m) using (18)
+end
+V. EXPERIMENTS
+In this section, we describe our experiments, the experimen-
+tal setup and the data used for the experiments.
+
+A. Datasets
+For our analysis, we use five different data sets. All the
+continuous values were normalized. Any sensors that had
+discrete values were formatted using one-hot encoding. The
+data sets are:
+• Secure Water Treatment (SWaT) [43]: This data set
+consists of data collected from a Secure Water Treatment
+system. The data is collected over 11 days of operation,
+of which 7 days of data show the normal operation and 4
+days of data were collected under an attack scenario. The
+data has 51 sensors and actuators. In addition, 5 seconds
+of data were aggregated.
+• Water Distribution (WaDi) [44]: The data is collected
+over 16 days of operation, out of which 14 days of
+data showed normal operation and 2 days of data were
+collected under an attack scenario. The data has 123
+sensors and actuators. In addition, 5 seconds of data were
+aggregated.
+• PUMP Data (PUMP) [7]: The data was collected from
+a water pump system from a small town. The data was
+sampled at every minute and collected over 5 months.
+• HTTP (HTTP) [5]: This data set is about HTTP service
+data. We are using a small subset of the data set which
+was obtained from [45]. From the subset, we manually
+split the test and train based on the number of consecutive
+normal points of data. The first 200001 points were all
+normal values and allocated towards the training set. The
+remaining 367497 points consist of mixed normal and
+abnormal values that were allocated towards the testing
+set.
+• Application Server Dataset (ASD) [34]: This public
+dataset contains data collected from an unspecified in-
+ternet company. The data set consists of 12 files. For the
+training set, we used 8640 training samples per file. For
+the testing set, we used 4320 samples per file.
+The details of the data set are shown in Table V-A.
+B. Analysis Metrics
+A desirable method for measuring accuracy of anomaly
+detection is to use point-adjusted metrics [46]. In point-
+adjusted metrics, a contiguous anomaly segment is considered
+as successfully detected if any point inside the segment is
+classified as an anomaly, Following the method described in
+[7], to measure the performance of our method, we enumerate
+all possible anomaly thresholds and search for the best possible
+point adjusted score.
+For measuring the efficacy of the model, we use two
+metrics: F1-score (F1) & MCC. F1 has been used in the
+past literature extensively as a good measure of accuracy of a
+model.
+The Matthew Correlation Coefficient (MCC) is a measure-
+ment metric for binary classification problems. It is considered
+as a better measurement metric than F1-score [22] as it consid-
+ers all four parameters in the confusion matrix (false positive,
+true positive, false negative & true negative). According to
+the literature F1 may be a too optimistic score for measuring
+accuracy in classification problems. Hence, we also use MCC
+as an additional metric for measuring the performance of our
+model. The MCC is defined as:
+MCC =
+T P ·T N−F P ·F N
+√
+(T P +F P )·(T P +F N)·(T N+F P )·(T N+F N)
+(19)
+where TP are the true positives, FP are the false positives
+and FN are the false negative.
+The MCC returns a value between −1 and +1. An MCC of
++1 represents a perfect prediction, a 0 is no better than ran-
+dom prediction and −1 indicates total disagreement between
+predicted labels and actual labels.
+C. Benchmark Models
+To demonstrate the benefits of our proposed methods,
+we compare our approach with the state-of-the-art methods,
+Specifically, we mainly focus on comparing with methods that
+have been released in the past few years:
+• Isolation Forest (IF) [5]: It is a popular residual-error
+based framework, which is also part of the Python library.
+The method serves as a comparison between density-
+based and residual-error based anomaly detection algo-
+rithms.
+• LSTM-AE [7]: This is a type of residual-based anomaly
+detection method that combines LSTM and AE. This
+method will serve as a benchmark which shows the
+improvement of EnKF and PF over using only neural
+networks.
+• Neural
+System
+Identification
+&
+Bayesian
+Filtering
+(NSIBF) [7]: Since our work is partially based on this
+paper and this work was shown to outperform all previous
+works, it seemed reasonable to use this paper as a
+benchmark for comparison. It also serves as a comparison
+of EnKF and PF over UKF.
+• Interfusion [9]: This work used Gibbs Sampler, a type
+of MCMC, for detecting anomalies. Since the focus of
+our work is on using the SMC methods, this was another
+work we chose to compare our model with.
+• Anomaly-Transformer [24]: Method for anomaly detec-
+tion using transformers. It was shown to outperform most
+of the other methods.
+• BEATGAN [31] & FGANomaly [32]: GAN based
+anomaly detection methods
+D. Results
+All the experiments were run using a window size of 5 for
+the PUMP dataset and 12 for all the other datasets. For BSSAD
+we reported the best F1 and MCC scores, which were obtained
+by running the experiments repeatedly with different random
+seeds (we used 100 random seeds). We implemented our filters
+with a different numbers of sigma points and particles. The
+results of the experiments are shown in Table V-C. The results
+show that BSSAD performs best out of all the methods. PF
+
+TABLE II
+DATASET DESCRIPTION
+Dataset
+Train Samples
+Test Samples
+Validation/Train
+Features
+Percent Anomaly/Test
+SWAT
+99360
+89984
+0.25/0.75
+51
+11.99
+WADI
+241921
+15701
+0.25/0.75
+93
+7.09
+PUMP
+76901
+143401
+0.25/0.75
+44
+10.05
+HTTP
+200001
+367497
+0.25/0.75
+3
+0.6
+ASD
+8640
+4320
+0.25/0.75
+19
+10.21
+TABLE III
+COMPARISON OF PERFORMANCE METRICS ON BENCHMARK DATASETS
+Dataset
+SWaT
+WaDi
+PUMP
+HTTP
+ASD
+F1
+MCC
+F1
+MCC
+F1
+MCC
+F1
+MCC
+F1
+MCC
+IF
+0.9141
+0.5081
+0.8984
+0.1086
+0.8629
+0.0252
+0.9560
+0.3391
+0.8549
+-0.0247
+LSTM-AE
+0.8150
+0.8084
+0.7692
+0.7550
+0.8450
+0.8301
+0.9765
+0.9764
+0.6837
+0.6550
+NSIBF
+0.9189
+0.9107
+0.9010
+0.8928
+0.9120
+0.9208
+0.9420
+0.9420
+0.8889
+0.8785
+Interfusion
+0.8645
+0.8572
+0.8696
+0.8598
+0.7204
+0.7213
+0.6734
+0.7100
+0.9401
+0.9335
+Anomaly Transformer
+0.7918
+0.7732
+0.9329
+0.9299
+0.8605
+0.8528
+0.4579
+0.5405
+0.9183
+0.9089
+BeatGAN
+0.7549
+0.7577
+0.2409
+0.1989
+0.4186
+0.3992
+0.5888
+0.6407
+0.9183
+0.9089
+FGANomaly
+0.9144
+0.7206
+0.5409
+0.1237
+0.9742
+0.7378
+0.0189
+0.0486
+0.8660
+0.1267
+BSSAD-EnKF-10
+0.8842
+0.8679
+0.7225
+0.7007
+0.9645
+0.9606
+0.8195
+0.8197
+0.7400
+0.7052
+BSSAD-EnKF-20
+0.8997
+0.8861
+0.8061
+0.7904
+0.9838
+0.9820
+0.9714
+0.9713
+0.8636
+0.8445
+BSSAD-EnKF-50
+0.9007
+0.8895
+0.7929
+0.7888
+0.9630
+0.9594
+0.6585
+0.6946
+0.8395
+0.8231
+BSSAD-PF-500
+0.9174
+0.9088
+0.9140
+0.9084
+0.8854
+0.8806
+0.9842
+0.9842
+0.9438
+0.9359
+BSSAD-PF-1000
+0.9189
+0.9107
+0.9417
+0.9386
+0.8849
+0.8799
+0.9816
+0.9816
+0.9231
+0.9125
+BSSAD-PF-2000
+0.9263
+0.9538
+0.9238
+0.9203
+0.8849
+0.8799
+0.9842
+0.9844
+0.9231
+0.9125
+has the highest F1 and MCC for both SWAT, WADI, HTTP
+and ASD data set compared to all three filters. EnKF shows
+the best performance for the PUMP data set. BSSAD is able
+to perform well on all data with small number of features and
+with small number of anomalies where most methods fail and
+perform poorly with very low F1 and MCC.
+In addition, the MCC metric also shows that only measuring
+F1 might not always be an indication that a method is good at
+detecting anomalies. In some cases the F1 score was high but
+the MCC was very low. BSSAD is able to achieve high F1
+and MCC showing that our method is very good at detecting
+anomalies.
+The modularity of BSSAD shows that we can fine-tune our
+model based on the data. We could change the number of
+particles or sigma points to improve the accuracy. We could
+even swap out filters depending on the input data. For example,
+we could use EnKF for the PUMP data set and PF for WADI
+or SWAT data set. It should be noted that choosing EnKF or PF
+comes at a computation cost. There is a trade-off between the
+speed of detecting anomalies and the accuracy of detection. In
+domains where accuracy is more important, like in the medical
+domain, PF might be more suitable. But in domains where
+speed of detection is more important, like in detecting cyber-
+attacks, it might be more suitable to use EnKF or UKF.
+In the future, we aim to explore in more detail the rela-
+tionship between data and the type of filter. We will also
+explore other methods for NNM like hierarchical or variational
+autoencoders. Another avenue for future research would be
+to explore different importance densities or prior pdfs, other
+forms of PF, like particle Markov Chain Monte Carlos (PM-
+CMC) [12], a type of MCMC algorithm that incorporates
+particle filters to estimate the posterior distribution. Then
+samples are repeatedly obtained from the posterior to more
+accurately estimate the next state.
+VI. CONCLUSION
+In this paper, we propose a novel and flexible model for
+anomaly detection in multivariate time series, called Bayesian
+State-Space Anomaly Detection (BSSAD). Our model com-
+bines neural networks and state-space algorithms to detect
+anomalies. The result of our analysis shows that BSSAD
+performs better than the state-of-the-art methods. Moreover,
+our method can be adapted for different data and domain
+by modifying state-space algorithms and neural networks to
+achieve better performance in detecting anomalies. In the
+future, we aim to further explore other state-space estimation
+methods and compare the differences in anomaly detection
+feasibility. We foresee the application of our model across
+multiple domains that use time-series data.
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+page_content='uc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='edu  Samuel Lin  University of Arkansas  Fayetteville, Arkansas, USA  smlin@uark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='edu  Jusin Zhan  University of Cincinnati  Cincinnati, OH, USA  zhanjt@ucmail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='uc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='edu  Abstract—Detecting anomalies in multivariate time series  (MTS) data plays an important role in many domains.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  abnormal values could indicate events, medical abnormalities,  cyber-attacks, or faulty devices which if left undetected could  lead to significant loss of resources, capital, or human lives.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In this paper, we propose a novel and innovative approach to  anomaly detection called Bayesian State-Space Anomaly Detection  (BSSAD).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The BSSAD consists of two modules: the neural network  module and the Bayesian state-space module.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The design of  our approach combines the strength of Bayesian state-space  algorithms in predicting the next state and the effectiveness of  recurrent neural networks and autoencoders at understanding  the relationship between the data to achieve high accuracy  in detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The modular design of our approach  allows flexibility in implementation with the option of changing  the parameters of the Bayesian state-space models or swap-  ping neural network algorithms to achieve different levels of  performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In particular, we focus on using Bayesian state-  space models of particle filters and ensemble Kalman filters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  We conducted extensive experiments on five different datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The experimental results show the superior performance of our  model over baselines, achieving an F1-score greater than 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='95.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In addition, we also propose using a metric called Matthew  Correlation Coefficient (MCC) to obtain more comprehensive  information about the accuracy of anomaly detection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Index Terms—Bayesian state-space models, Particle filters,  Ensemble Kalman filters, Anomaly detection  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' INTRODUCTION  Anomaly detection in multivariate time series (MTS), also  referred to as outlier or novelty detection, is the task of de-  tecting data that deviates significantly from expected behavior.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  A multivariate time series consists of more than one time-  dependent variable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Each variable depends not only on its  past values but also has a dependency on other variables.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In  the medical domain or cyber-physical system, these variables  could be sensors measurement like temperature, pressure, etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Anomaly detection has applications in many domains.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For  example, in event detection [1], in the financial domain to  identify fraud, in cyber-security to identify cyber-attacks, for  identifying medical risks, or for fault detection in cyber-  physical systems [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Detecting anomalous behavior in multivariate time series  has been an active area of research for a long time [3], [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Most of the previous works have focused on presenting mul-  tivariate time series as a collection of single time dependant  variables without focusing on the dependencies between the  variables [5], [6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' These works have been classified as residual-  based anomaly detection [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In residual-based anomaly de-  tection, recurrent neural networks or autoencoders are usually  implemented to predict future values [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Then the predicted  and the actual values are compared to calculate a residual error.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Any error that exceeds a threshold value greater than the actual  value is classified as an anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Recently, there has been a  focus on designing methods that consider multivariate time  series as a whole by finding relationships along the temporal  domain and between the features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The results from these  methods have been highly promising [7], [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' These methods  have been referred to as density-based algorithms and have  been able to achieve higher accuracy compared to residual-  based algorithms in detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Density-based algorithms detect anomalies in multivariate  time series data using Bayesian Theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In Bayesian theory, the  next state of a system is estimated by constructing the posterior  probability density function of the data from a prior distribu-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It is assumed that normal data is sampled from a posterior  density function different from the one that anomalous data is  sampled from.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Hence, any data point that does not follow the  same distribution or deviates significantly from the distribution  followed by the normal data will be flagged as an anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The most common state estimation techniques include Kalman  filters and its variants [10], Sequential Monte Carlo (SMC) and  Markov Chain Monte Carlo (MCMC) methods [11], [12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Implementing Bayesian state-space algorithms for anomaly  detection in multivariate time series has significant obstacles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  One obstacle is that to properly estimate the state, key knowl-  edge about the mathematical relationship between the features  (sensors) and their values along the time domain is required.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Most of the previous works on state estimation have been built  using physics equations [13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' But that may not always be the  case and definite mathematical models between the variables  may not be available.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Another key obstacle is that there is no  information about the posterior distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  To deal with these obstacles, we propose a novel and  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='13031v1  [cs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='LG]  30 Jan 2023  innovative density-based anomaly detection algorithm called  Bayesian State-Space Anomaly Detection (BSSAD).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Our  method consists of two main modules: the neural network  module (NNM) and the Bayesian state-space module (BSSM).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The NNM is based on recurrent neural networks and autoen-  coders.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The BSSM is implemented using Bayesian state-space  estimation techniques of ensemble Kalman filters (EnKF) and  particle filters (PF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Our method is motivated by the density-based algorithm  presented in [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To develop mathematical relationships be-  tween the variables, we use a combination of recurrent neural  networks, more specifically long short-term memory (LSTM)  [14], and autoencoders (AE).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' LSTM and AE have been widely  used for anomaly detection [15]–[17].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The Bayesian state-  space techniques estimate the posterior distribution using a  Monte Carlo (MC) method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In MC methods, the posterior  distribution is represented as a set of random samples from  a known distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' As the number of samples increases,  the true posterior probability density function (pdf) can be  estimated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Both EnKF and PF are types of MC methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In contrast to the algorithm in [7], which implemented  a variant of the Kalman filter called an unscented Kalman  filter (UKF) [18], [19] to detect anomalies, our work im-  plements ensemble Kalman filters (EnKF) and particle filters  (PF) for constructing the posterior distribution and detecting  the anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' UKF, EnKF, and PF can efficiently handle  continuous, multivariate, and non-linear systems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' PF have  an added advantage of being able to handle multimodal,  extremely non-Gaussian noise, and occlusions problems [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Previous research has shown that both EnKF [13], [20] and  PF [21] have been shown to have better accuracy in estimating  the next state when compared to UKF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Once the posterior distribution has been obtained, we calcu-  late the Mahalanobis distance to find the distance between the  current state and the predicted distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Any value whose  distance exceeds a threshold is considered an anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The contribution of our work is as follows:  Formulation & Algorithm: We propose the novel Bayesian  State-Space Anomaly Detection (BSSAD) 1 model that utilizes  state-space algorithms and neural networks to detect anoma-  lies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We implement our model using Ensemble Kalman filters  (EnKF) and particle filters (PF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To the best of our knowledge,  no other works have focused on using EnKF and PF for  anomaly detection in multivariate times series data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Accuracy: We applied our model to multiple data sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  results of our analysis showed that our model can achieve  a F1-score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In addition, we propose to use the Matthews  correlation coefficient (MCC) to measure the accuracy of  anomaly detection as an alternative to the F1-score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' MCC has  been considered as a better metric than F1-score in binary  classification tasks [22].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Generality: The modular design of our model allows it to  be highly flexible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Different parameters can be changed and  1https://github.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='com/BSSAD2022/BSSAD  algorithms can be easily swapped out so that our method can  be applied to different data types and across multiple domains.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The paper is organized as follows: In Section II we provide  a review of related literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In Section III, we provide an  overview of key concepts that are necessary for building our  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In Section IV, we present our model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In Section V  we present our experiments and observations and finally, in  Section VI we conclude.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' LITERATURE REVIEW  There are many different anomaly detection algorithms  available in the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Typically, anomaly detection al-  gorithms are classified as supervised or unsupervised.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Some  researchers have proposed other classification techniques for  anomaly detection methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In [7], anomaly detection al-  gorithms were classified as residual-error based and density  based.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Residual-error based methods predict the next value and  find the difference between the predicted and actual values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Density-based methods find the distribution of the data and  data is flagged as an anomaly if it is not part of the distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In [23], the anomaly detection algorithms were classified  as statistics-based, classification-based, vocabulary-based, and  reconstruction-based.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Statistics-based methods are similar in  definition to density-based algorithms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The data is assumed  to follow a normal distribution and a variable is classified as  normal if it is within the 3σ range.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Classification is usually  done using labeled data with high accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' However, labeled  data is hard to obtain, thus the use of unlabeled methods  is more common.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Vocabulary-based methods aim to find  patterns in time-series data and data deviating from these  patterns is classified as an anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Finally, reconstruction-  based methods are similar to residual-error based methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Most work found in the literature aims at using recon-  struction or residual-error based methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' One of the most  common methods that have served as a benchmark for many  other methods is the Isolation Forest [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The isolation forest  is based on a tree-based architecture to identify anomalies but  it is not made for multivariate time-series data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Neural networks, more specifically recurrent neural net-  works (RNN) and autoencoders or a combination of both,  have recently become very popular as a method to detect  anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' An extensive review of the application of deep  learning techniques in anomaly detection can be found in [2],  [3], and [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Recently, transformers have also been proposed  for detecting anomalies [24].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' They renovate transformers for  anomaly detection by adding an anomaly-attention mecha-  nism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Most works have focused on implementing long-short term  memory (LSTM), a type of RNN, for reconstruction [25], [26].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  One example of using autoencoders for anomaly detection  was USAD [6], [27], [28].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Methods combining both LSTM  and autoencoders to detect anomalies include [15]–[17], [29]  and [30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Generative adversarial networks (GAN) have also  been proposed for anomaly detection [31], [32].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' All these  methods are classified as residual-error or reconstruction-based  anomaly detection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Anomalies in sensor data  Algorithms that can be classified as density or statistical-  based anomaly detection include [33] and Omnianomaly [34].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  These methods use generative models to predict the distribu-  tion of the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Bayesian state-space methods are also examples of density-  based algorithms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Even though these methods have mainly  been applied for next state estimation [10], [21], [35], there  have been some works that have applied Bayesian state-space  estimation for anomaly detection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' However, most of the work  has been restricted to fault detection [36] or anomaly detection  in videos [37] and [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Ensemble Kalman filters have not been  used for anomaly detection and have only been implemented  for state estimation in weather or medical domains [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In [9], hierarchical variational autoencoders combined with  Markov Chain Monte Carlo (MCMC) is used to learn temporal  and inter-sensor correlation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' A data point is flagged as an  anomaly if it does not follow the temporal or inter-sensor  correlation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' A relevant work that has implemented Bayesian  state-space algorithms was called Neural System Identification  and Bayesian Filtering [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In [7] the AE and LSTM methods  are improved further by adding a unscented Kalman Transform  (UKF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' UKF is able to learn the temporal and inter-sensor  relationship and is able to approximate the distribution of the  next state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  III.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' PRELIMINARIES  Figure 1 shows how anomalies would manifest in real-world  data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The anomalies would represent deviations from past  patterns not only along the time-domain but also between dif-  ferent sensor values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In this section, we describe the Bayesian  state-space model which forms the basis for our BSSM and  can be used to find the relationships between the past values  of the features and between different features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In particular, we  present the theory behind EnKF and PF which we implement  in our model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In a Standard multivariate times series data can be rep-  resented as X = (x0, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=', xT ), xϵRMwhere x are M features  (also referred to as sensors, or variables), that can produce  continuous or discrete values (when x is discrete, it is referred  to as control input in the literature) and T is the time interval  over which the sensor values were obtained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' A state-space  evolution is defined by two equations:  zt = Ft(zt−1, qt−1)  (1)  xt = Ht(zt, rt)  (2)  Equation (1) is the state transition equation [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the  equation, zt and zt−1 are the hidden state variables at time  t and t−1 respectively (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' actual value of a sensor), qt−1 is  an i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' process noise, and Ft is the state transition function  that maps the previous state (zt−1) to the current state (zt).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Equation (2) is the measurement equation [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the  equation xt is the observed measurement at time t, zt is  the hidden measurement (state) of the sensor, rt is the i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  measurement noise and Ht is the measurement function that  maps the hidden states (zt) to the observed measurements (zt).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The objective is to estimate the state zt given the state  x1:t = xi, i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='., t up to time T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' From a Bayesian perspec-  tive, the objective is to construct the pdf p(zt|x1:t).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The pdf  is constructed recursively in two stages: prediction and update  [21] represented by (1) and (2), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It is assumed that  the initial state is the pdf p(z0|x0) ≡ p(z0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the prediction  stage, the system model in (1) is used to obtain the prior pdf  of the state at time t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Assuming that the prior pdf is given as  p(zt−1|x1:t−1), then the prediction equation is:  p(zt|x1:t−1) =  �  p(zt|zt−1)p(zt−1|x1:t−1)dzt−1  (3)  It should be noted that p(zt|zt−1) is equivalent to the state  transition equation from (1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In the update stage, zt is used to modify the prior pdf to  obtain the required posterior pdf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The update stage is then  defined as:  p(zt|x1:t) = p(xt|zt)p(zt|x1:t−1)  p(xt|x1:t−1)  (4)  where p(xt|x1:t−1)  =  �  p(xt|zt)p(zt|x1:t−1)dzt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the  above equation p(xt|zt) is defined from the measurement  model in (2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The solution to these equations is obtained recursively but  cannot be determined analytically.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The optimum solution can  only be obtained in certain cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For example, the Kalman  filter assumes that the posterior distribution and the noise  are Gaussian and Ft and Ht are linear.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' However, in most  cases, these assumptions are not true.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In such cases, only  sub-optimal solutions exist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Extended Kalman filter (EKF),  Unscented Kalman filter (UKF) [18], [19], Ensemble Kalman  filter (EnKF) [39], [40] and Particle filters (PF) [21] are  examples that provide approximate solution to the posterior  pdf [10], [21], [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In sub-optimal methods, the objective is  to generate samples from a known prior distribution, propagate  these samples using (1) and (2) and obtain the posterior  distribution from the result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' These samples are referred to as  sigma points in UKF and EnKF and particles in PF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the  following sections, we will describe in detail how the posterior  distribution is estimated using EnKF and PF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  600  500  400  300  200  100  0  1  20001  40001  60001  80001  100001  120001  140001  sensor33  sensor34  sensor35  AnomalyA.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Ensemble Kalman Filter  EnKF are non-linear approximations to the state estimation  problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The EnKF is very similar to UKF [10] but different  in some ways.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In UKF, a set of weighted sigma points  are generated deterministically and are passed through the  state transition and measurement functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The mean and  covariance of the sigma points are an approximate measure of  the posterior pdf’s state mean and covariance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' However, EnKF  relies on Monte Carlo simulation to generate a large number  of sigma points from a known distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The generated  sigma points are then propagated using the state transition  and measurement function in a similar way to UKF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Another  difference is that unlike UKF, where the sigma points are  generated at each iteration, in EnKF the sigma points are  randomly generated based on a distribution only in the initial  stage, and are then propagated at each iteration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The first step in designing the EnKF is the initialization  stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the initial stage N sigma points (χ) are generated  using a known mean and variance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Like any Bayesian state-  space algorithm, there is a predict stage and an update stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The implementation of the EnKF varies in different literature  [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The predict stage consists of passing the N sigma points  (χ) through state transition function (Ft) to obtain χf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  predict stage is implemented using the following equation:  χf = Ft(χt−1) + Nq  (5)  Nq is the state transition noise matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  As mentioned in Section III, the purpose of the update  stage is to update the sigma points and obtain the posterior  mean and covariance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The posterior mean and covariance  are the estimates for the posterior distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The updated  sigma points and the posterior mean and covariance become  the prior state, mean and covariance for the next iteration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  There are multiple ways of implementing the update state and  there is no clear consensus on which way to use [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We  propose to implement the update state using the following set  of equations, which gave us the best performance:  χh = Ht(χf) + Nr  µz = 1  N  N  �  1  χh  Pzz = 1  N  N  �  1  [χh − µz][χh − µz]T  Pxz =  1  N − 1  N  �  1  [χf − µt−1][χh − µz]T  K = PzzP −1  xz  χt = χf + K[xt − χh + er]  ˆµt = 1  N  N  �  1  χt  ˆPt = Pt−1 − KPzzKT  (6)  The sigma points are first passed through the measurement  function to obtain the hidden state χh.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Using χh the mean µz  is calculated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Next, we calculate Pzz and Pxz which are the  auto-correlation between χh and the cross-correlation between  χh and χf, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Pzz and Pxz are used to calculate  the Kalman Gain, K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In our equations, we chose to change  the method of calculating Pxz and use µt−1 instead of xt−1  [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The K is a key parameter in the EnKF framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It is  the weight given to the current state estimate and the actual  state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Its purpose is to automatically tune the filter to estimate  the next state as accurately as possible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The sigma points  (χt) are updated using the Kalman gain (K) which serves as  input sigma points for the next stage.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Nr is the measurement  noise matrix and er is perturbation added to the sigma points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Finally, using the updated sigma points χt, the posterior pdf  can be estimated as state mean ˆµt and covariance ˆPt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Particle Filter  Particle filters belong to a class of Monte Carlo (MC) meth-  ods called sequential MC (SMC) filters [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' They are based  on the sequential importance sampling (SIS) algorithm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Other  SMC algorithms include bootstrap filtering, condensation al-  gorithm, interacting particle approximations, and survival of  the fittest [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Like EnKF, SMC algorithms also generate  sigma points (which are called particles) sampled from a  known probability distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' However, unlike EnKF each  particle is assigned a weight.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The posterior distribution can  then be estimated from the weighted particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' As the number  of particles reaches infinity, a true representation of posterior  pdf can be obtained.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  A generic SIS particle filter consists of the following steps:  Generate samples called particles from a known distribu-  tion.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Assign each particle a weight  Resample the particles based on the updated weights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Calculate the state and measurement mean and covariance  using the particles and their weights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The posterior distribution is estimated using the equation:  p(zt|x1:t) ≈  Ns  �  i=1  ωi  tδ(zt − xi  t)  (7)  where  ωi  t ∝ ωi  t−1  p(xt|xi  t)p(xi  t|xi  t−1)  q(xi  t|xi  t−1, xt)  (8)  Here, δ(�) is an indicator function, xi  t are the particles  that are sampled from a known distribution q(�) (also called  importance density).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Ns are the number of particles sampled  from q(�).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' xt is the input data, zt is the hidden state and wt  i  is the ith weight at time t and �  i ωi  t = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The weights are  chosen using the principal of importance sampling and the  details of the derivation of the equations can be found in [21],  [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  A common problem with particle filters is particle degener-  acy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Particle degeneracy happens when after a few iterations,  Fig.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' BSSAD Model  all but one particle will have negligible weight.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Once that  happens the filter will be unable to estimate the next state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' A  measure for particle degeneracy is the effective sample size,  Neff.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' However, Neff cannot be measured directly and only  an estimate can be calculated [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The equation for Neff is:  ˆNeff =  1  �Ns  i=1(wi  t)2  (9)  There are two main ways of reducing particle degeneracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  One is through good choice of importance density, and the  other is through resampling [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The importance density can  be chosen using another state-space estimation method like  Kalman filters, unscented transform, or using a Gaussian esti-  mate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For our model, we consider using a Gaussian estimate  for importance density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The second method of resampling may be computationally  expensive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Hence, a common technique is to resample when-  ever a significant degeneracy is observed, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' when Neff  falls below a threshold NT .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The concept of resampling is  to remove all particles with small weights and focus more  on particles with large weights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Some of the resampling  methods found in the literature are multinomial, stratified,  residual, and systematic resampling [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In this paper, we  use systemic resampling schemes as it is the most popular of  the resampling algorithms and performs the best amongst all  the other resampling methods [10], [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  A variation on the SIS particle filter is the sampling im-  portance resampling (SIR) filter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The SIR filter is an MC  method that can be applied to recursive Bayesian state-space  problems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The SIR filter incorporates the state transition and  measurement functions to propagate and update the parti-  cles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The advantage of the SIR filter is that the importance  weights are easy to calculate and importance density can  be easily sampled.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In an SIR filter, the importance density  q(zt|xi  t−1, x1:k) = p(zt|xi  t−1) and the particles are resam-  pled at each step.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Consequently, the weights are given by  wi  t ∝ wi  t−1p(xt|xi  t) where wi  t−1 =  1  Ns .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  IV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' METHODOLOGY  The overall methodology can be found in Figure 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Our  method consists of two main modules: the neural network  module (NNM) and the Bayesian state-space module (BSSM).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The basis for BSSM is to use state-space methods to predict  the mean and covariance of the distribution of the next state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  If the sensor value deviates significantly from the predicted  distribution, then it is an anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The first step in the anomaly  detection model is to design the state-space model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The focus  of this paper is to use EnKF and SIR-PF to estimate the  posterior distribution by estimating the state mean (ˆµt) and  the state covariance matrix ( ˆ  Pt).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In order to design EnKF and  PF, there are four main parameters that must be determined:  state transition equation F that maps the previous states  to the current state  process noise q  measurement equation H that maps the state to the hidden  (measurement) state  measurement noise r  Since, there are no predefined set of mathematical equations,  in this paper, we follow the model presented in [7] to estimate  F, q, H, and r.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' These parameters were estimated using recur-  rent neural networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Specifically, F is estimated using long  short-term memory (LSTM) [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The measurement equation  H is estimated from an autoencoder which maps the input to  a lower latent dimension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Both LSTM and autoencoders by  themselves have been used for anomaly detection [4], [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' By  adding a spate space algorithm that leverages autoencoders and  LSTMs, the accuracy of anomaly detection can be significantly  improved.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In the upcoming sections, we will describe the implemen-  tation details of our modules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Neural Network Module (NNM)  The NNM consists of two subnets which are referred to as F  and H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Each of these subnets have their own parameters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  subnet F takes in state variables to provide times-series esti-  mates for the state transitions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It combines the input from zt−1  and xt−τ:t−1, where τ is the window size, to obtain the next  state estimate zt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It is defined as F : (zt−1, xt−τ:t−1)ϵRM ′ →  ztϵRM ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the autoencoder, the encoder H is defined as  H : xtϵRτ×M → ztϵRτ×M ′ where M are the number of  sensors that are mapped onto a hidden dimension M ′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' This  is equivalent to the measurement function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Consequently, the  decoder maps the hidden state zt back to the state variable xt  and is defined as H−1 : ztϵRW ×M ′ → ˆxtϵRW ×M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The neural network is trained using data with normal values,  X(n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The normal data is first divided into training(X(n)  train)  and validation set (X(n)  val).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' X(n)  train is used to train the NNM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Following [7], the loss function of the neural network is  defined as:  L =  T  �  t=τ  α1||xt−1 − ˆxt−1||2  2 + α2||xt − ˆxt||2  2 + α3||zt − zt−1||2  2  (10)  where ˆxt and ˆxt−1 are the reconstruction data and zt and  zt−1 are the hidden states for t and t − 1 respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In  the equation, the first two terms are the reconstruction and  prediction errors for sensor values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The third factor is for  smoothing the consecutive hidden states and ensuring that the  hidden states are close to each other.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The model is trained  using the ADAM [42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  qt  rt  (K /wl)  Zt  xt-1  F  H  BSSM  Ut, I  H  Zt-1  NNM :TABLE I  HYPERPARAMETERS  Hyperparameter  Dataset  Value or Range  w1  ALL  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='45  w2  ALL  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='45  w3  ALL  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='45  τ  PUMP  5  τ  WADI  12  τ  SWAT  12  τ  HTTP  12  τ  ASD  12  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Dimensions For zt  PUMP  [1, 120]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Dimensions For zt  WADI  [1, 200]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Dimensions For zt  SWAT  [1, 75]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Dimensions For zt  HTTP  [1, 200]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Dimensions For zt  ASD  [1, 200]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Hidden Layers for H  ALL  [1, 3]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Dense Layers for F  ALL  [1, 3]  NUM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' LSTM Layers for F  ALL  [1, 3]  NUM Dimensions in Hidden Layers  ALL  [32, 256]  Training Epochs  ALL  100  In addition, process and measurement noise are calculated  from the neural network.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The noise is calculated using X(n)  val.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The process noise q is found using the following equation:  qt = H(xt) − F(H(xt−1), xt−τ:t−1)  (11)  Similarly, the measurement noise is found using the equa-  tion:  rt = xt − H−1(H(xt))  (12)  Using qt and rt, the process covariance matrix Q and  measurement noise covariance matrix R can be found, which  we use later in our state estimation equations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  For training the neural network, we followed the guidelines  provided in [7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To guide the hyperparamter tuning of the  model, we used the uniform negative sampling algorithm to  generate anomalous values.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Next, a randomized grid search  algorithm was used to fine-tune the hyperparameters and the  model with the best anomaly detection performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  hyperparameter summary is given in Table IV-A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Anomaly Detection using Bayesian State-Space Module  (BSSM)  In this section, we explain the implementation of the BSSM  and designing of the state-space method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The BSSM is applied  to the data set that contains both normal and anomalous  data (denoted X(a)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The state-space algorithm calculates the  posterior probability p(zt|xt−τ:t−1) and determines a value xt  to be an anomaly if it is not part of the posterior distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Using the state transition function and measurement function  from the NNM, the state-space equations are:  zt = F(zt−1, xt−τ:t−1) + qt  (13)  xt = H−1(zt) + rt  (14)  It is assumed that both qt and rt are sampled from a Gaus-  sian distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Hence, qt ∽ N(z0, Q) and rt ∽ N(0, R)  where Q is the process noise covariance matrix and R is  the measurement noise covariance matrix, ˆz0 = H(x0) and  P0 = αI, where I is the identity matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' α is a factor for  scaling the covariance matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  1) Ensemble Kalman Filter Design: In this section we  explain the implementation detail of EnKF using (5) and (6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The problem with implementing EnKF from the equations is  that the filter did not converge.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We implementing EnKF using  equations obtained from NNM by sampling the sigma points  from a normal distribution that is an estimation of the hidden  state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We call our proposed algorithm Neural Network EnKF  (NN-EnKF) (Algorithm 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Algorithm 1: Neural Network Ensemble Kalman Filter  (NN-EnKF)  Data: Input multivariate time series data, XϵRM×T ,  M sensors and T time values  Result: Estimated states, ˆµϵR1×M, ˆPϵRM×M  Initialization: χ ∽ N(ˆz0, P0);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  for i = 1 : T do  /* Predict using (5)  /  χh = F(χt−1, xt−τ:t−1);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  /* Update using (6)  /  χf = H−1(χh);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Find Pzz, Pxz&K;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Sample er ∽ N(0, R);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Update Sigma Points: χt ← χf + K[xt − χh + er];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Estimate state: ˆµt ← 1  N  �N  i=1 χt;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Estimate state covariance ˆPt ← Pt−1 − KPzzKT  end  Using (5) and (6), the updated equations are;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  χh = F(χt−1, xt−τ:t−1)  χf = H−1(χh)  (15)  Where the sigma points χt are used to represent the  hidden state and is sampled from a normal distribution,  χt ∽ N(ˆz0, P0), χϵRN where N are the number of sigma  points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' χh is the result after the state transition function is  applied to χt and χf are the sigma points transformed back  from the hidden state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  For initialization, to enable the filter to converge, α was  set at a high value (which was 100).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It was observed that the  state transition and process noise are set to 0 as they did not  seem to make any contributions to the accuracy of the state  estimation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Instead, we sampled the error perturbation from a  multivariate normal distribution with mean 0 and covariance  R - er ∽ N(0, R), erϵRN where N are the number of sigma  points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Using Pxx and Pxz, K can be calculated which is used to  update the sigma points.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The updated sigma points become the  input for the next state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The mean and variance of the sigma  points become the state estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  2) Particle Filter Design: The next novel algorithm we use  in BSSM is the modified version of SIR-PF called Neural  Network SIR PF (NN-SIR).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The first step is choosing the  importance density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We choose a Gaussian distribution as the  importance density.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The particles are sampled from a normal  distribution, xi  t ∽ N(ˆz0, P0), i = 1 : Ns where Ns are number  of particles and P0 is found with a very small α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The weights  are initialized as wi =  1  Ns where i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='Ns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The state mean  and covariance can be estimated using the following equations:  Xh = F(Xt−1, xt−τ:t−1) + qt  Xf = H−1(Xh) + rt  (16)  In the equation Xt−1 = xi  t−1, i = 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='Ns, Xh is the result  after the state transition function is applied to Xt−1 and Xf  are the sigma points transformed back from the hidden state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The state transition noise is sampled from a normal distri-  bution defined by qt ∽ N(ˆz0, Q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The process noise is also  sampled from a normal distribution defined by rt ∽ N(0, R).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  At each iteration, the weights are updated by finding the  squared error distance between Xh and xt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To measure the  distance, we use the radial basis kernel function (RBF).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  RBF is defined as:  rbf(xt, Xf) = exp(||xt − Xf||2  2σ2  )  (17)  where σ is a scaling number.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The weights are then updated  by Wu = W ∗ rbf(xt, Xf) where W = wi  t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='.wNs  t .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  updated weights are like probabilities that determine how sig-  nificant each particle is in relation to the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The state mean  and state covariance can then be determined from Xh and  Wu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To avoid particle degeneracy, the particles are resampled  using systematic resampling as described in Section III-B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Systematic resampling gave the best performance for PF and  we chose this resampling method.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We set Nt = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To further  avoid degeneracy, Nrs (we used Nrs = 1) percent of the  particles are resampled from the prior Gaussian distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The resampled particles are the input to the next state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  algorithm for the NN-SIR filter is given in Algorithm 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  3) Anomaly Detection: Let the predicted state mean and  covariance be represented as ˆµt and ˆPt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The anomaly score  can be found as the distance between the actual state and the  predicted mean and covariance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' To the find the distance, we  use the Mahalanobis distance [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The Mahalanobis distance  is defined as:  m =  �  (xt − ˆµt)T ˆP −1  t  (xt − ˆµt)  (18)  A larger m, indicates a higher likelihood for xt to be an  anomaly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The anomaly threshold can be adaptive based on  previous values or a hard threshold can be set or using the  Algorithm 2: Neural Network SIR Particle Filter (NN-  SIR)  Data: Input multivariate time series data, XϵRM×T ,  M sensors and T time values  Result: Estimated states, ˆµϵR1×M, ˆPϵRM×M  Initialization: Sample xi  t ∽ N(ˆz0, P0), i = 1 : Ns and  assign weight wi  t =  1  Ns for i = 1 : Ns;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  for t = 1 : T do  for i = 1 : Ns do  /* propagate weights  /  xi  t = H−1((F(xi  t−1xt−τ:t−1) + qt) + rt;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  normalize weights: wi  t =  wi  t  �Ns  i=1 wi  t ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  end  /* Update Particles  /  if ˆNeff < NT then  {xi  t, wi  t}Ns  i  = RESAMPLE({xi  t, wi  t}Ns  i )  end  Resample xi  t ∽ N(ˆz0, P0), i = 1 : Ns ∗ Nrs  Estimate state: ˆµt ←  1  Ns  �N  i=1 wi  txi  t ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Estimate covariance:  ˆPt ←  1  �Ns  i=1 wi  t  �Ns  i=1 wi  t(xi  t − ˆµt)  end  algorithm defined in [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' A value is considered to be an  anomaly if its Mahalanobis is above a specific threshold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The complete algorithm for our model Bayesian State-Space  Anomaly Detection (BSSAD) is given in Algorithm 3  Algorithm 3: Bayesian State-Space Anomaly Detec-  tion (BSSAD)  Data: Input multivariate time series data, XϵRM×T ,  M sensors and T time values  Result: Anomaly Scores (m)  Initialization:  Split X into normal only (X(n)) and normal &  anomalous data (X(a));' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Split X(n) into X(n)  train and X(n)  val;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Train neural network using X(n)  train;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Estimate noise on X(n)  val using (11) and (12);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Divide X(a) into window size τ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  for t = 1 : T  τ do  Estimate ˆµt and ˆPt for X(a) using Algorithm 1 or  2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Calculate anomaly score (m) using (18)  end  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' EXPERIMENTS  In this section, we describe our experiments, the experimen-  tal setup and the data used for the experiments.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Datasets  For our analysis, we use five different data sets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' All the  continuous values were normalized.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Any sensors that had  discrete values were formatted using one-hot encoding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  data sets are:  Secure Water Treatment (SWaT) [43]: This data set  consists of data collected from a Secure Water Treatment  system.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The data is collected over 11 days of operation,  of which 7 days of data show the normal operation and 4  days of data were collected under an attack scenario.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  data has 51 sensors and actuators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In addition, 5 seconds  of data were aggregated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Water Distribution (WaDi) [44]: The data is collected  over 16 days of operation, out of which 14 days of  data showed normal operation and 2 days of data were  collected under an attack scenario.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The data has 123  sensors and actuators.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In addition, 5 seconds of data were  aggregated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  PUMP Data (PUMP) [7]: The data was collected from  a water pump system from a small town.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The data was  sampled at every minute and collected over 5 months.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  HTTP (HTTP) [5]: This data set is about HTTP service  data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We are using a small subset of the data set which  was obtained from [45].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' From the subset, we manually  split the test and train based on the number of consecutive  normal points of data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The first 200001 points were all  normal values and allocated towards the training set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  remaining 367497 points consist of mixed normal and  abnormal values that were allocated towards the testing  set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Application Server Dataset (ASD) [34]: This public  dataset contains data collected from an unspecified in-  ternet company.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The data set consists of 12 files.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For the  training set, we used 8640 training samples per file.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For  the testing set, we used 4320 samples per file.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The details of the data set are shown in Table V-A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Analysis Metrics  A desirable method for measuring accuracy of anomaly  detection is to use point-adjusted metrics [46].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In point-  adjusted metrics, a contiguous anomaly segment is considered  as successfully detected if any point inside the segment is  classified as an anomaly, Following the method described in  [7], to measure the performance of our method, we enumerate  all possible anomaly thresholds and search for the best possible  point adjusted score.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  For measuring the efficacy of the model, we use two  metrics: F1-score (F1) & MCC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' F1 has been used in the  past literature extensively as a good measure of accuracy of a  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The Matthew Correlation Coefficient (MCC) is a measure-  ment metric for binary classification problems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It is considered  as a better measurement metric than F1-score [22] as it consid-  ers all four parameters in the confusion matrix (false positive,  true positive, false negative & true negative).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' According to  the literature F1 may be a too optimistic score for measuring  accuracy in classification problems.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Hence, we also use MCC  as an additional metric for measuring the performance of our  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The MCC is defined as:  MCC =  T P ·T N−F P ·F N  √  (T P +F P )·(T P +F N)·(T N+F P )·(T N+F N)  (19)  where TP are the true positives, FP are the false positives  and FN are the false negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The MCC returns a value between −1 and +1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' An MCC of  +1 represents a perfect prediction, a 0 is no better than ran-  dom prediction and −1 indicates total disagreement between  predicted labels and actual labels.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Benchmark Models  To demonstrate the benefits of our proposed methods,  we compare our approach with the state-of-the-art methods,  Specifically, we mainly focus on comparing with methods that  have been released in the past few years:  Isolation Forest (IF) [5]: It is a popular residual-error  based framework, which is also part of the Python library.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The method serves as a comparison between density-  based and residual-error based anomaly detection algo-  rithms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  LSTM-AE [7]: This is a type of residual-based anomaly  detection method that combines LSTM and AE.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' This  method will serve as a benchmark which shows the  improvement of EnKF and PF over using only neural  networks.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Neural  System  Identification  &  Bayesian  Filtering  (NSIBF) [7]: Since our work is partially based on this  paper and this work was shown to outperform all previous  works, it seemed reasonable to use this paper as a  benchmark for comparison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It also serves as a comparison  of EnKF and PF over UKF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Interfusion [9]: This work used Gibbs Sampler, a type  of MCMC, for detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Since the focus of  our work is on using the SMC methods, this was another  work we chose to compare our model with.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Anomaly-Transformer [24]: Method for anomaly detec-  tion using transformers.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It was shown to outperform most  of the other methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  BEATGAN [31] & FGANomaly [32]: GAN based  anomaly detection methods  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Results  All the experiments were run using a window size of 5 for  the PUMP dataset and 12 for all the other datasets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For BSSAD  we reported the best F1 and MCC scores, which were obtained  by running the experiments repeatedly with different random  seeds (we used 100 random seeds).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We implemented our filters  with a different numbers of sigma points and particles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The  results of the experiments are shown in Table V-C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The results  show that BSSAD performs best out of all the methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' PF  TABLE II  DATASET DESCRIPTION  Dataset  Train Samples  Test Samples  Validation/Train  Features  Percent Anomaly/Test  SWAT  99360  89984  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
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+page_content='75  51  11.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='99  WADI  241921  15701  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
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+page_content='09  PUMP  76901  143401  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
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+page_content='05  HTTP  200001  367497  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
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+page_content='21  TABLE III  COMPARISON OF PERFORMANCE METRICS ON BENCHMARK DATASETS  Dataset  SWaT  WaDi  PUMP  HTTP  ASD  F1  MCC  F1  MCC  F1  MCC  F1  MCC  F1  MCC  IF  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
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+page_content='9125  has the highest F1 and MCC for both SWAT, WADI, HTTP  and ASD data set compared to all three filters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' EnKF shows  the best performance for the PUMP data set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' BSSAD is able  to perform well on all data with small number of features and  with small number of anomalies where most methods fail and  perform poorly with very low F1 and MCC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In addition, the MCC metric also shows that only measuring  F1 might not always be an indication that a method is good at  detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In some cases the F1 score was high but  the MCC was very low.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' BSSAD is able to achieve high F1  and MCC showing that our method is very good at detecting  anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  The modularity of BSSAD shows that we can fine-tune our  model based on the data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We could change the number of  particles or sigma points to improve the accuracy.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We could  even swap out filters depending on the input data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' For example,  we could use EnKF for the PUMP data set and PF for WADI  or SWAT data set.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' It should be noted that choosing EnKF or PF  comes at a computation cost.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' There is a trade-off between the  speed of detecting anomalies and the accuracy of detection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In  domains where accuracy is more important, like in the medical  domain, PF might be more suitable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' But in domains where  speed of detection is more important, like in detecting cyber-  attacks, it might be more suitable to use EnKF or UKF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  In the future, we aim to explore in more detail the rela-  tionship between data and the type of filter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We will also  explore other methods for NNM like hierarchical or variational  autoencoders.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Another avenue for future research would be  to explore different importance densities or prior pdfs, other  forms of PF, like particle Markov Chain Monte Carlos (PM-  CMC) [12], a type of MCMC algorithm that incorporates  particle filters to estimate the posterior distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Then  samples are repeatedly obtained from the posterior to more  accurately estimate the next state.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  VI.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' CONCLUSION  In this paper, we propose a novel and flexible model for  anomaly detection in multivariate time series, called Bayesian  State-Space Anomaly Detection (BSSAD).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Our model com-  bines neural networks and state-space algorithms to detect  anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' The result of our analysis shows that BSSAD  performs better than the state-of-the-art methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Moreover,  our method can be adapted for different data and domain  by modifying state-space algorithms and neural networks to  achieve better performance in detecting anomalies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' In the  future, we aim to further explore other state-space estimation  methods and compare the differences in anomaly detection  feasibility.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' We foresee the application of our model across  multiple domains that use time-series data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  REFERENCES  [1] U.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Anjum, V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Zadorozhny, and P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Krishnamurthy, “Tbam: Towards an  agent-based model to enrich twitter data,” in 18th ISCRAM Conference  Proceedings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  Virginia Tech.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=', ISCRAM Blacksburg, VA (USA), 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  [2] G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Pang, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Shen, L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Cao, and A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' Hengel, “Deep learning for  anomaly detection: A review,” ACM Computing Surveys (CSUR), vol.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' 54,  no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' 2, pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content=' 1–38, 2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
+page_content='  [3] V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/u9FPT4oBgHgl3EQfNzRd/content/2301.13031v1.pdf'}
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+arXiv:2301.01198v1  [math.NT]  3 Jan 2023
+New applications of the Mellin transform
+to automorphic L–functions
+Laurent Clozel
+Introduction
+In an earlier paper [2], and its Appendix, written with Peter Sarnak, we
+have obtained universal lower bounds on certain quadratic integrals of auto-
+morphic L–functions. For instance, if π is a cuspidal unitary representation
+of GL(m, AQ), and L(s) = L(s, π):
+(0.1)
+� +∞
+−∞
+���L(1/2 + it)
+1/2 + it
+���
+2
+dt > π
+2 .
+Cf [2, Theorem D]. In this article, we follow some questions that arose nat-
+urally in this context.
+The first one was suggested by a remark of Sarnak, according to which we
+cannot have such universal bounds for short intervals, e.g. for the integral
+on [−1, 1] in (0.1); at least such cannot be obtained if m is allowed to vary.
+See the Introduction to [2], § 2.
+The argument does not succeed if m is fixed; neither did the author suc-
+ceed in finding, for m fixed, an absolute bound on a short interval. This
+remains an interesting problem.
+In Chapter 2, we obtain a universal lower bound, for m fixed, for the
+integral on an interval [−A log C, A log C] where C is the analytic conductor.
+Even then, we could not obtain a fixed lower bound.
+Rather, we prove
+that this integral is larger than c(log C)−1/2 where c > 0 is an absolute
+constant. This may not be optimal, but it is commensurable with the Lindel¨of
+conjecture.
+(We hope that an analytic number theorist familiar with the
+use of the Mellin transform, as in the proof of the approximate functional
+equation, will be able substantially to improve this result.) Moreover, we can
+shift the ordinate and obtain a general result on an interval [X − T, X + T]
+where X is arbitrary and T is of the order of log X.
+See Theorem 2.2,
+1
+
+Theorem 2.3. The proof relies on a theorem of Molteni [14], further improved
+by Xiannan Li [12].
+In Chapter 3, we follow a lead from [2, §3.3]. There we considered Vino-
+gradov’s Conjecture on the order of the first quadratic non–residue and we
+showed that it followed directly, via the Mellin transform, from the Lindel¨of
+conjecture (including in the q–aspect) for the associated Dirichlet L–function.
+(This may have been well–known to experts).
+A similar problem is, given a non trivial representation ρ of a Galois group
+Gal(E/F) of number fields, to determine “the” first prime p of F — i.e. one
+of smallest norm — where ρ is unramified and ρ(Frobp) ̸= 1, Frobp being a
+Frobenius element. The proof of [2] extends naturally. We have treated first
+the case where ρ is a one–dimensional character, in Chapter 3, § 1–3. See
+Theorem 3.1. When ρ is non–Abelian, the proof is more delicate and leads us
+to introduce the unramified variant L(s, ρ) of the Artin L–function L(s, ρ).
+See Theorem 3.2.
+In §3.6, we show that our estimate is, in some cases, better that the known
+unconditional estimates. (The relevant result here is the recent one of Zaman
+[21]) However we have to assume that F is a Galois extension of Q and, more
+crucially, that L(s, ρ) is holomorphic. Note that we do not have to assume
+that ρ is associated to an automorphic representation.
+In Chapter 4, we have reviewed some odds and ends concerning the results
+and arguments of [2]. In particular we point out that they apply to Rankin L–
+functions — not only to the standard L–functions of [2]; and we develop the
+remarks made in [2] about the relation between estimates on the summation
+function A0(x) — see § 2.1— and subconvexity for L(s, π).
+Finally, in Chapter 1, we have recalled some “well–known” results con-
+cerning the growth of L–functions in the critical strip, in term of the analytic
+conductor. Fortunately we could rely on the very clear exposition of Har-
+cos [5]. For the convenience of the reader, we also collect some formulas for
+special functions.
+We use notation standard in analytic number theory, in particular Lan-
+dau’s symbols ≪, O( ), indexed when we want to specify the dependence of
+the implicit constants. We use f ≺ g (f, g positive functions) for f/g → 0.
+We use A for an absolute constant (in the context), not always the same in
+different occurrences.
+Acknowledgement.- I thank Farrell Brumley, Jesse Thorner and Asif Za-
+man for providing useful references, and Peter Sarnak for suggesting that
+2
+
+my lower bounds should be compared with the well-known bound of Ra-
+machandra. I also thank the Fondation Simone et Cino del Duca for financial
+support.
+1
+Majorations and formulas
+1.1
+In this preliminary chapter we have grouped together the majorations and
+formulas which will be used in the text, and crucially in using an “absolute”
+version, due to Molteni, of the Friedlander–Iwanieˇc estimate.
+We briefly
+recall our set–up, which is that of [2]. We consider a unitary cuspidal rep-
+resentation π of GL(m, A), or a product π = π1 × π2 × · · · × πr (parabolic
+induction) of cuspidal representations πi of GL(mi, A), m = � mi. Then
+L(s, π) =
+r�
+i=1
+L(s, πi).
+is the standard L–function. The completed L–function
+Λ(s, π) = Ds/2 L(s, π∞) L(s, π),
+where D is the conductor, an integer ≥ 1, satisfies a functional equation
+Λ(s, π) = ε(π)Λ(1 − s, ˜π).
+For details and a review of the other L–functions to which these theorems
+apply, see [2, § 2.1].
+We do not assume, as we did in [2], that π∞ is self–dual. The functional
+equation can than be written
+(1.1)
+L(1 − s, π) = ε(π)γ(s)L(s, ˜π)
+with
+γ(s) = (π−mD)s−1/2
+c(˜π∞)Γ(s, ˜π∞)
+c(π∞)Γ(1 − s, π∞)
+and
+Γ(s, π∞) =
+m
+�
+j=1
+Γ
+�s + cj
+2
+�
+3
+
+with
+Re(cj) ≥
+1
+m2 + 1 − 1
+2
+[13].
+Following Iwanieˇc and Sarnak, we associate to π its conductor D = D(π)
+and its analytic conductor
+(1.2)
+C = C(π) = D(π)
+m
+�
+j=1
+(2 + |cj|)
+as well as
+C(s) = C(π, s) = C(π) (1 + |s|)m.
+(There is a finer version of C(s) ; cf [7, p. 95] for a discussion of this.) We
+will need uniform estimates, in terms of these data, for γ(s) and L(s, π) in a
+strip Re(s) ∈] − ε, 1 + ε[.
+1.2
+We recall the known bounds on γ(s) and L(s). For γ(s) a uniform bound
+is derived by Harcos [5]. See however the corrections in [6], in particular [6,
+(3)] which corrects [5, 3.22]1.
+Lemma 1.1. (Harcos) For σ > 1
+m −
+1
+m2+1, Re(s) = σ,
+γ(s) ≪
+σ C(s)σ−1/2.
+We now assume the Ramanujan conjecture for π.
+Fix ε > 0 (small.)
+Since πf is tempered, we have L(s, ˜π) ≪ 1 for Re(s) = 1 + ε, uniformly for
+m fixed. For such a value of s, γ(s) ≪ C(s)1/2+ε. The functional equation
+then implies
+L(s, π) ≪ C(s)1/2+ε
+for Re(s) = −ε.
+We deduce from the Phragm´en–Lindel¨of principle:
+Proposition 1.1. Assume πf tempered. For −ε ≤ Re(s) ≤ 1 + ε,
+L(s, π) ≪ε C(s)
+1−σ
+2 +ε.
+Cf. Iwanieˇc–Kowalski [7, p. 100].
+1I thank Farrell Brumley for this reference.
+4
+
+1.3
+Here we insert a few remarks on the analytic conductor. It is not true that,
+for A > 0 fixed, there exist a finite number of representations π such that
+C(π) ≤ A. Indeed, if m = 1, and π = χ is a Dirichlet character of conductor
+D, twisted by | |a, (a ∈ iR), the analytic conductor is D(2 + |a|).
+This
+phenomenon persists in higher rank m, but is essentially due to the center
+GL(1) of GL(m).
+Proposition 1.2. For any A > 0, there exist a finite number of cuspidal
+representations π of GL(m, A) whose central character ω verifies ω|R×
++ = 1
+and such that C(π) < A.
+Since D(π) < C(π) there is a finite number of possibilities for D(π). Let S
+denote the connected component of 1 in the center Z(R) ∼= R× of GL(m, R).
+Consider the space L = L2
+cusp(S GL(m, Q)\GL(m, A)) of L2–cusp forms in-
+variant by S. The Hecke algebra �
+v
+Hv (where H∞ = C∞
+c (GL(n, R)) and,
+for v = p finite, Hp is the algebra of compactly supported smooth functions)
+acts on L2
+cusp by right translations, and it is well–known that this action is
+trace–class. Fix D ≥ 1, and let K(D) ⊂ GL(m, Af) be the congruence sub-
+group defined by Jacquet, Piaterskii-Shapiro and Shalika [8, §5, Th´eor`eme],
+and ϕD ∈ �
+p
+Hp its characteristic function. Then ϕD projects L onto its
+subspace composed of the K(D)–invariants in the cuspidal representations π
+(with ωπ|R×
++ = 1). This is an infinite sum of representations ρ of GL(m, R);
+a function ϕ∞ ∈ C∞
+c (GL(m, R)) acts on it by a trace–class operator. In par-
+ticular, any compact subset of the unitary dual of GL(m, R) contains only a
+finite number of such representations. But the set of representations ρ such
+that C∞(ρ) = �(2 + |cj|) ≤ A is compact. (See [2, § 2.2] for the relation
+between the cj and the Langlands parameters of π∞.)
+Assume again π cuspidal. For a ∈ i R, let π[a] = π ⊗ | det |a. We can
+choose a such that π[a] has trivial central character on R×
++. In view of this,
+it is useful to know the relation between C(π) and C(π[a]).
+Again we refer to [2, § 2.2]. The representation π∞ is associated to a sum
+of real characters
+ν(x) = (sgnx)ε|x|c
+(x ∈ R×
++); ε = 0, 1)
+5
+
+and of characters of C×:
+µ(z) = zp(¯z)q, p − q ∈ Z.
+(The result of Luo–Rudnick–Sarnak [13] implies simple bounds on Re(c),
+Re(p + q).)
+The datum cj associated to ν is c + ε; the data cj associated to µ are
+(q, q + 1)
+if
+Re(p − q) < 0
+(p, p + 1)
+if
+Re(p − q) > 0.
+If we twist by | |a, the cj are transformed into cj + a. Therefore
+(1.3)
+C(π[a]) ≤ C(π)(1 + |a|)m.
+We also remark that if C(π) = 2m, D(π) = 1 and the cj are equal to 0.
+Under this assumption, the number of π is therefore finite.
+Finally, it is of interest to know when ω|R×
++ = 1 in terms of the cj. However
+the relation is not direct. The real characters νj contribute cj = c + ε, where
+νj(x) = xc, x > 0; A complex character µ(z) determines a representation π2
+of GL(2, R) of central character xp+q (x > 0), and cj, cj′ equal to (q, q + 1)
+or (p, p + 1). One checks that cj + cj′ = p + q + n where n = |p − q| > 0 is
+the ramification of π2. Therefore the central character of π∞, on R×
++, is xA,
+A =
+�
+cj − Ram(π∞),
+where
+Ram(π∞) =
+�
+ε +
+�
+n
+is the ramification of π∞. To obtain a representation with ω|R×
++ = 1, we have
+to twist by | det|−A/m. The new conductor is (very roughly) bounded by
+C(π)(1 + |A/m|)m.
+1.4
+For the reader’s convenience we recall a few facts on special functions. We
+will use the functions
+Erf(x)
+=
+� x
+0
+e−t2dt,
+Erfc(x)
+=
+� ∞
+x
+e−t2dt = 1
+2
+√π − Erf(x).
+6
+
+See [3, p. 147]. In particular we have the asymptotic expansion of Erfc(x)
+for x ≫ 0:
+Erfc(x) = 1
+2e−x2(x−1 + O(x−3)).
+We will also need an estimate for
+I(a, T) =
+� ∞
+T
+e−t2tadt
+(T > 0).
+This is best computed as an incomplete gamma function. With
+Γ(a, x)
+=
+� ∞
+x
+e−ttadt
+t ,
+I(a, T)
+=
+� ∞
+T
+e−t2ta+1dt
+t
+= 1
+2
+� ∞
+T 2 e−ss
+a+1
+2 ds
+s
+= 1
+2Γ
+�a + 1
+2
+, T 2�
+and the asymptotic expansion [3, p. 135]
+Γ(a, x) = xa−1e−x(1 + O(1
+x))
+now yields
+I(a, T) = 1
+2T a−1e−T 2(1 + O(T −2)).
+2
+The quadratic integral of L(1/2+it)
+1/2+it
+on short
+intervals
+2.1
+In this section we assume m fixed; we consider π verifying the assumptions
+in (1.1). We write
+L(s)
+= L(s, π),
+L(s, π)
+=
+�
+ann−s,
+A0(x)
+=
+�
+n≤x
+an
+(x ≥ 1).
+7
+
+We assume given ξ, ν > 0 and consider only π such that ν ≥ σc(π) where
+σc(π) is the abscissa of convergence of L(s, π). We assume that we have, for
+x ≥ 1 and any ε, an estimate
+(2.1)
+A0(x) ≪ε Cξ xν+ε
+where the implicit constant depends only on ε, and C = C(π). For a suitable
+function f on R×
++, we define
+�
+Mf(s) =
+� ∞
+0
+f(x)x−sdx
+x .
+Lemma 2.1. (cf. [2, § 3.3]) For Re(s) > ν, the integral defining �
+MA0(s) is
+absolutely convergent and �
+MA0(s) = L(s)
+s .
+Indeed
+� X
+0
+� �
+n≤x
+an
+�
+n−sdx
+x
+=
+�
+n≤X
+an
+� X
+n
+x−s−1dx
+= 1
+s
+�
+n≤X
+ann−s − 1
+s
+� �
+n≤X
+an
+�
+X−s.
+Since Re(s) > σc(π), the first sum converges to L(s, π) for X → ∞. The
+second is dominated by Xν+ε/2X−ν−ε → 0.
+For σ > ν, we then have
+(2.2)
+� ∞
+1
+x−σA0(x)x−itdx
+x = L(σ + it)
+σ + it
+.
+In order to obtain a minoration of the L2–norm of
+L( 1
+2 +it)
+1/2+it on an interval
+[−T, T], we consider its scalar product with a Gaussian. Thus let, for α > 0:
+gα(t) = e−παt2.
+We extend gα to a function of s, equal to gα(t) for s = 1/2 + it. Thus
+Gα(s) = eπα(s−1/2)2.
+8
+
+This is a function of rapid decrease in t (s = σ + it), uniformly in any
+vertical strip. In particular, for σ > ν:
+(2.3)
+�
+σ
+L(s)
+s
+Gα(s)ds = i
+� +∞
+−∞
+L(1/2 + it)
+1/2 + it
+gα(t)dt
+since L(s) and Gα(s) have no poles. We estimate the left–hand side using
+the Fourier transform. We have by (2.2)
+� ∞
+0
+e−σXA0(eX)e−itXdX = L(σ + it)
+σ + it
+,
+i.e.
+L(σ + it)
+σ + it
+= F(e−σXA0(eX))
+where
+Fh(t) =
+� +∞
+−∞
+h(X)e−itXdX.
+The inverse transformation is
+(2.4)
+F −1k(X) = 1
+2π
+� +∞
+−∞
+k(t)eitXdt.
+The scalar product formula is
+�
+k1(X)k2(X)dX = 1
+2π
+�
+h1(t)¯h2(t)dt.
+However, (2.3) is a bilinear product, and then:
+�
+h1(t)h2(t)dt = 2π
+�
+k1(X)k2(−X)dX.
+Therefore the left–hand side of (2.3) is equal to the product of i = √−1 and
+of
+(2.5)
+2π
+� ∞
+0
+e−σXA0(eX) ˆGα(−X)dX
+where ˆGα(X) is given by (2.4) applied to k(t) = Gα(σ + it). Now
+(2.6)
+Gα(σ + it) = eπα(σ−1/2)2e−παt2e2πα(σ−1/2)it.
+9
+
+We have
+F −1k(X) = 1
+2πF −1
+0 k( X
+2π)
+where F0, F −1
+0
+denote the usual Fourier transforms, normalised by 2π. Now
+F −1
+0 (f(t)e2iπβt)
+= F −1
+0 f(X + β),
+F −1
+0 (e−παt2)
+=
+1
+√αe− π
+αX2
+so F −1
+0 Gα)(X) is, by (2.6), equal to
+eπα(σ−1/2)2 1
+√αe− π
+α(X+α(σ−1/2))2
+=
+1
+√αe− π
+αX2e−2πX(σ−1/2),
+and
+F −1Gα(−X) =
+1
+2π√αe− X2
+4πα e(σ−1/2)X.
+2.2
+We now consider the integral (2.5), equal to
+(2.7)
+1
+√α
+� ∞
+0
+e−σXA0(eX)e− X2
+4πα e(σ−1/2)XdX
+=
+1
+√α
+� ∞
+0
+A0(eX)e− X2
+4παe− X
+2 dX.
+(It is, as it should be in view of the translation of complex integrals, inde-
+pendent of σ.)
+For 1 ≤ x ≤ 2, A0(x) = 1. We first obtain a lower bound for
+I1 :=
+1
+√α
+� log 2
+0
+e− X2
+4παe− X
+2 dX.
+In the sequel, Landau’s symbols O( ), ≪, . . . , unindexed, are used when the
+implicit constants are absolute. We have
+I1 ≥
+�
+1/2 1
+√α
+� log 2
+0
+e− X2
+4πα dX.
+10
+
+We set X =
+√
+4παY ; the integral is then
+2√π
+� log 2/2√πα
+0
+e−Y 2dY
+=
+2√πErf
+� log 2
+2√πα
+�
+=
+2√π
+�1
+2
+√π − Erfc
+� log 2
+2√πα
+��
+.
+For x → ∞, Erfc(x) =
+1
+2xe−x2(1 + O( 1
+x2)). For small α, then,
+I1 ≥ π
+�
+1/2 − O
+�√α e− log2 2
+4πα
+�
+and I1 ≥ π
+2 := 2c for α sufficiently small.
+We now have to estimate the remainder, dominated by
+I2 =
+1
+√α
+� ∞
+log 2
+Cξ e(ν+ε−1/2)Xe− X2
+4πα dX.
+Write θ = ν + ε − 1/2, and set
+Y = X − 2πθα.
+The exponential term in the integrand is then
+exp
+�
+− Y 2
+4πα
+�
+eπθ2α.
+We can neglect the constant since α will be small. Thus I2 is dominated by
+I3
+=
+1
+√α
+� ∞
+ℓ
+Cξe−
+1
+4πα X2dX,
+ℓ = log 2 − 2πθα.
+for small α, so the part relative to [ℓ, log 2] is dominated by Cξ√α · e−a1/α
+with a1 > 0 fixed. We now consider
+I4 = Cξ
+� ∞
+log 2
+1
+√αe−
+1
+4πα X2dX.
+11
+
+The integral is equal to 2√π Erfc( log 2
+2√πα) (see the formulas in § 1); it
+admits an expression
+(2.8)
+√π e− log2 2
+4πα
+�2√πα
+log 2 + O(α3/2)
+�
+for small α. This (multiplied by Cξ) is of the same order as the integral
+on the small segment.
+We want to ensure that this is dominated by I1, which is implied by
+√α e− a2
+α Cξ ≤ a3
+where a3 is a small constant, i.e.
+1
+2 log α − a2
+α + ξ log C ≤ −a4
+(a4 > 0). We may assume α ≤ 1, so we seek
+(2.9)
+a2
+α ≥ a4 + ξ log C.
+Since C ≥ 2m, ξ log C > a5 > 0 and
+1
+a4 + ξ log C >
+1
+Nξ log C
+for N such that a4 < (N − 1)ξ log C, so N is determined by constants inde-
+pendent of π.
+Thus (2.9) is verified if
+(2.10)
+α ≤
+a5
+log C .
+We summarise the result
+Proposition 2.1. Assume π cuspidal, and σc(π) ≤ ν. There exist positive
+constants c, b1 (depending only on ξ, ν) such that if C = C(π) and
+α ≤
+b1
+log C ,
+then
+���
+� +∞
+−∞
+L(1/2 + it, π)
+1/2 + it
+gα(t)dt
+��� ≥ c.
+12
+
+2.3
+We can now apply the previous proof by using a theorem of Molteni [14].
+Theorem 2.1. (Molteni). Assume π is a cuspidal, unitary representation of
+GL(m, A). Then
+�
+n≤x
+|an| = Oε(Cεx1+ε)
+(x ≥ 1).
+(The implicit constant depends only on m and ε.) In fact Molteni proves a
+stronger result:
+�
+n≤x
+|an|
+n
+= O(Cεxε).
+Thus, in the previous proof, we may take ν = 1, ξ = ε. (This has been
+improved by Xiannan Li [12]; the improved estimate seems irrelevant to
+us, but the theorem extends to automorphic representations satisfying the
+conditions in §1.1) The assumption σc(π) ≤ ν is of course satisfied.
+We have given an exposition of the proof valid for other exponents, be-
+cause of the following fact. Consider only representations π that are tem-
+pered, i.e. satisfy the Ramanujan Conjecture. Assume moreover π∞ self–
+dual. Then by a result of Friedlander and Iwanieˇc, (2.1) is satisfied with
+ξ =
+1
+m+1, ν = m−1
+m+1. (See [4]; the self–duality condition is implicit there, and
+made explicit in [2].) However Friedlander and Iwanieˇc consider only the
+arithmetic conductor, so (2.1) is replaced by
+A0(x) ≪ D
+1
+m+1x
+m−1
+m+1 +ε.
+They must also assume that π∞ is bounded, i.e.
+C∞(π) = �(2 + |ci|)
+bounded. Their estimate with respect to x is better, but this does not seem
+to play any role in the present proof.
+The fact that these representations π verify σc(π) ≤ m−1
+m+1 is proved in [2].
+We will unfortunately have to assume the Ramanujan conjecture in the
+next paragraph.
+13
+
+2.4
+In order to exploit Proposition 2.1 to obtain a lower bound on a “short”
+interval, we must now estimate the tail
+I5(T) =
+� ∞
+T
+L(1/2 + it)
+1/2 + it
+gα(t)dt
+(and the opposite one). In order to have uniform estimates, we must now
+assume that π verifies the Ramanujan Conjecture. We now have
+L(1
+2 + it) ≪ C(t)
+1
+4 +ε.
+Fix gα(t) = e−παt2 with α =
+b1
+log C. For T ≥ 1,
+(2.11)
+I5(T) ≪ C
+1
+4+ε
+� ∞
+T
+e−παt2t
+m
+4 −1+εdt.
+We need an estimate for
+� ∞
+T
+e−παt2tadt;
+as recalled in Chapter 1,
+� ∞
+T
+e−παt2tadt = 1
+2π−1α−1T a−1e−παT 2·
+·
+�
+1 + O
+� 1
+παT −2��
+.
+We want to ensure that |I5(T)| ≤ 1
+4c; i.e.
+C
+1
+4+εα−1T a−1e−παT 2�
+1 + O
+� 1
+αT −2��
+≪ 1.
+We assume provisionally that T can be chosen such that 1
+αT −2 is small. Then
+this is implied by
+(2.12)
+1
+2 log C − log α + (a − 1) log T − παT 2 ≤ −X
+where X is a positive constant; here a = m
+4 − 1 + ε; we replace a by a value
+such that a − 1 > 0. With α =
+b1
+log C, we want to ensure
+παT 2 − a log T ≥ X − log α + 1
+2 log C,
+14
+
+which yelds
+πb1T 2 − a log C log T ≥ log C(X′ + log log C + 1
+2 log C).
+Assume T 2 = A1 log2 C for a large positive constant. The left–hand side is
+then
+πb1A1 log2 C − a log C(log log C + log
+�
+A1) ≥ A2 log2 C
+for A1 sufficiently large and C ≥ 2m, and this dominates the right–hand side.
+Moreover, 1
+αT −2 ≪ (log C)−1A−2
+1
+≤ 1
+2 for A1 sufficiently large (independently
+of C), as assumed previously. Therefore:
+Lemma 2.2. For T = A log C, where A is a sufficiently large positive con-
+stant, and α =
+b1
+log C,
+���
+�
+|t|≥T
+L(1/2 + it)
+1/2 + it
+gα(t)dt
+��� ≤ c
+2.
+Now the absolute value of the integral for |t| ≤ T is ≥ c
+2. Thus
+(2.13)
+Sup
+t∈[−T,T]
+���L(1/2 + it)
+1/2 + it
+��� ≥ c
+2
+���
+�
+t≤T
+gα(t)dt
+���
+−1
+(2.14)
+���L(1/2 + it)
+1/2 + it
+���
+2
+���gα(t)
+���
+2 ≥ c
+2
+where the L2–norms are computed in [−T, T].
+We now have to estimate the integral, and quadratic integral, of gα(t) on
+[−T, T]. We have
+� T
+0
+e−παt2dt
+=
+� √παT
+0
+e−s2(√πα)−1ds
+= a6(log C)1/2
+� a7(log C)1/2
+0
+e−s2ds
+≍ (log C)1/2
+and the same estimate is true for the quadratic integral. Therefore we obtain
+15
+
+Theorem 2.2. There exist absolute, positive constants A, c1, c2 such that
+for any cuspidal π verifying the Ramanujan Conjecture
+(i)
+Sup
+t∈[−T,T]
+���L(1/2 + it), π
+1/2 + it
+��� ≥ c1(log C)−1/2
+(ii)
+� T
+−T
+���L(1/2 + it), π
+1/2 + it
+���
+2
+dt ≥ c2(log C)−1/2
+if T ≥ A log C, C = C(π).
+It may be noticed that in (i) the Lindel¨of Conjecture yields an estimate
+≪ (log C)ε (for T of order A log C).
+We have used the cuspidality of π only in order to rely on Molteni’s result;
+Xianan Li’s result makes this unnecessary.
+We can now use the remarks in §1.3 on the translation of integrals to
+obtain lower bounds on L( 1
+2+it, π) on short intervals, not necessarily centered
+in 0. We have
+L(s, π[X] = L(s + iX, π)
+C(π[X]) ≤ C(π)(1 + |X|)m
+log C(π[X]) ≤ log C(π) + m log(1 + |X|).
+Let
+S =
+Sup
+t∈[−T,T]
+���L(1/2 + it, π[X])
+1/2 + it
+���.
+By Theorem 2.2, for T ≥ A log C(π[X]):
+S ≥ c1(log C + m log(1 + |X|))−1/2.
+However
+S =
+Sup
+t∈[−T,T]
+���L(1/2 + i(t + X), π
+1/2 + it
+��� ≤ 2 Sup
+t∈[−T,T]
+|L(1/2 + i(t + X, π)|
+Thus we have the following result on “short intervals”.
+Theorem 2.3. There exist absolute, positive constants A, c3, c4 > 0 such
+that for any cuspidal π verifying the Ramanujan Conjecture
+(i)
+Sup
+t∈[X−T,X+T]
+|L(1/2 + it, π)| ≥ c3 · (log C(π) + m log(1 + |X|))−1/2.
+16
+
+(ii)
+� X+T
+X−T
+��� L(1/2 + it, π
+1/2 + i(t − X)
+���
+2
+dt ≥ c4(log C(π) + m log(1 + |X|))−1/2
+if T ≥ A(log C + log(1 + |X|), C = C(π).
+The absolute constants depend only on m.
+Sarnak suggested that the estimate (ii) should be compared with the lower
+bound on short intervals obtained by Ramachandra in [18]. (Ramachandra
+notes that his proof, written for the Riemann zeta function, will extend to
+L-functions with Euler products. See [18, Remark 3].) In fact, because of
+the large denominator in the integral, our lower bound seems better than
+the one that follows obviously from Ramachandra’s. We assume X positive
+and large and T small with respect to X. (In the next lines the constant A
+depends on the formula.) Then Ramachandra’s estimate is
+� X+T
+X
+|L(1/2 + it)|2dt ≥ AT log T, T ≥ A log log X
+while here we obtain
+� X+T
+X−T
+��� L(1/2 + it, π
+1/2 + i(t − X)(
+���
+2
+dt ≥ A(log C + log X)−1/2
+for T ≥ A(log C + log X).
+For fixed C, our condition on T implies Ramachandra’s.
+We consider
+T ≈ A log X. The denominator in our formula is smaller than T 2. Thus
+Ramachandra’s bound implies for the integral
+� X+T
+X−T
+��� L(1/2 + it, π
+1/2 + i(t − X)
+���
+2
+dt
+a lower bound in AT −1 log T. But for T ≈ A log X, (log X)−1 log log X is
+dominated by our bound (log X)−1/2. Thus, for fixed C, the results do not
+seem commensurable. (It would be interesting to know how the conductor
+enters in Ramachandra’s formula.)
+17
+
+3
+The first non–trivial Frobenius element in
+a Galois representation
+3.1
+In this chapter we consider a non–trivial, irreducible representation ρ :
+Gal(E/F) → GL(m, C), where E/F is a Galois extension of number fields.
+If ρ is unramified at a prime p of F, we can consider the image ρ(Frobp), a
+conjugacy class in GL(m, C). We want to obtain a lower bound β on the
+first value of Np such that ρ is unramified and ρ(Frobp) ̸= 1. Of course, this
+is complicated by the presence of ramification, i.e., there may be a ramified
+prime q such that Nq ≤ β. If m = 1, this applies to Artin characters of A×
+F.
+3.2
+We first consider the Abelian case, m = 1.
+If F = Q, we are looking
+at primitive Dirichlet characters
+mod q = D. If L(s, χ) ≪ (q|s|)µ+ε for
+Re(s) =
+1
+2, it was shown in [2, § 3.3] that β ≪ q2µ+ε. Since Petrow and
+Young [17] have proved the Weyl bound µ ≤
+1
+6, we obtain by this simple
+application of the Mellin transform
+(3.1)
+For χ a primitive Dirichlet character
+mod q, β(x) ≪
+ε q1/3+ε.
+Of course this is much weaker than Burgess’s bound (for q prime)
+β(χ) ≪
+ε q
+1
+4√e+ε.
+However, we can now extend the method to Artin characters of A×
+F for an
+arbitrary number field F.
+So let χ be a character of finite order, and ρ the 1–dimensional represen-
+tation of Gal(Fχ/F) associated to χ by class field theory. We consider the
+L–function L(s, χ) as a L–function over Q. All the conditions in the paper of
+Friedlander–Iwaniec are met — this will also be the case for a Galois repre-
+sentation of degree > 1. We therefore have the properties of L(s, χ) recalled
+in § 2.3.
+Rather than the formulas in [2], we use the Mellin transform as in § 2.1.
+18
+
+Thus let
+L(s, χ)
+=
+�
+n
+ann−s,
+A0(x)
+=
+�
+n≤x
+an
+and
+(3.2)
+�
+M A0(x) =
+� ∞
+1
+A0(x)x−s dx
+x .
+Let ν0 be the exponent of Friedlander–Iwaniec:
+ν0 = d − 1
+d + 1, d = [F : Q].
+so
+(3.3)
+A0(x)≪
+d,εD
+1
+d+1xν0+ε
+(x ≥ 1).
+We note that the Archimedean data (cj) associated to χ are uniformly
+bounded, so the constant depends only on (d, ε). Moreover (3.2) is obtained
+by Friedlander–Iwaniec for x ≥ D1/2 (see a correction in [2, § 2.5]) but it is
+trivial for x ≤ D1/2 since |an| ≪ nε′ for any ε′ > o.
+The integral in (3.2) is absolutely convergent for Re(s) > ν0, say Re(s) =
+ν > ν0. The function A0(x)x−ν then belongs to L2(R×
++, dx
+x ). It follows (cf.
+Titchmarsh [19]) that L(s)
+s
+is L2 on the line Re(s) = ν, and that
+(3.4)
+� ∞
+1
+|x−νA0(x)|2dx
+x = 1
+2π
+�
+ν
+���L(s)
+s
+���
+2
+|ds|.
+However, if ν is close to ν0, the convergence of the right–hand side does not
+follow from convexity: see [2, § 3.2]; we will review this in Chapter 4. As a
+consequence we cannot use Proposition 1.1 to estimate the right–hand side.
+By Proposition 1.1, we have µ(ν) ≤ d
+2(1 − ν), so µ(ν) < 1
+2 if ν > 1 − 1
+d.
+The convergence of the right–hand side then follows from convexity and we
+have again by Proposition 1.1:
+Lemma 3.1. For ν > 1 − 1
+d,
+�
+ν
+���L(s)
+s
+���
+2
+|ds| ≪ D1−ν+ε.
+19
+
+3.3
+We now want to obtain a lower bound for the left–hand side of (3.4). We
+consider the integral on [1, β] where β is the norm of the first unramified
+prime such that χ(p) ̸= 1.
+Before doing so we recall the expression of the “absolute” conductor D.
+Let DF be the absolute value of the discriminant of F; let f(χ) be the con-
+ductor of χ (seen as a character of A×
+F), an ideal of F. Then
+(3.5)
+D = DF NF/Qf(χ).
+We need an expression for A0(x), for x < β. It is then given by
+an =
+�
+Na=n
+a(a)
+where � a(a)Na−s is the expression of L(s, χ) as an L–function over F, and
+Na < β, which implies that the factorization of a involves only primes p with
+Np < β. We have
+Lp(s, χ) = (1 − Np−s)−1
+if χ is unramified at p and Np < β,
+Lq(s, χ) = 1
+is χ is ramified at q. If a = � qαi
+i
+� p
+βj
+j (where we use {qi} to denote all the
+ramified primes), this implies that
+a(a) = 0
+if αi > 0 for some i, and a(a) = 1 otherwise. Thus, up to x = β, A0(x) is a
+variant of the summation function for ζF:
+(3.6)
+A0(x) =
+�
+n≤x
+�
+Na=n
+(qi,a)=1
+1
+where the condition (qi, a) = 1 is imposed for all i. Let B0(x) be the sum-
+mation function for ζF. The difference B0 − A0 is then
+(3.7)
+�
+n≤x
+�
+Na=n
+′1
+20
+
+where �′ is restricted by the condition
+(3.8)
+∃ i : qi|a.
+At this point it is necessary to extend the main result of [4]. Very generally,
+assume π is a tempered representation of GL(m, A); assume π is a product
+π1 ×· · · πr of cuspidal representations (with at most a factor mi = 1, πi = 1);
+assume π∞ self-dual. Let A0(x) be the associated summation function. Let
+κ be the residue of L(s, π) at 1. We write D for the conductor of π.
+Proposition 3.1. For x ≥ 1,
+A0(x) = κx + O(D
+1
+m+1 +εx
+m−1
+m+1 +ε)
+where the implicit constant depends only on m, ε and the Archimedean pa-
+rameters of π.
+For the function ζF, the implicit constant depends only on d and ε.
+For x ≥ D1/2 this is the result of [4]. For x ≤ D1/2, it was already noticed
+in § 3.2 that A0(x) ≪ D
+1
+m+1x
+m−1
+m+1 +ε. (This does not depend on the fact that
+L(s) is holomorphic.) If x ≤ D1/2, D
+1
+m+1x−
+2
+m+1 ≥ 1 and it suffices to check:
+κ ≪ (Dx)ε
+which is true since κ ≪ Dε, cf. [7, p. 100]. (For a zˆeta function, this is the
+easy part of the Brauer–Siegel theorem.)
+We can now apply this to B0:
+B0(x) = κx + O(D
+1
+d+1+ε
+F
+x
+d−1
+d+1+ε),
+κ = Ress=1ζF(s). Now fix i and consider the sum (3.7), the condition being
+qi|a. By a change of variables,
+�
+Na≤x
+qi|a
+1 =
+�
+Nb≤ x
+qi
+1
+where qi = Nqi and b ranges over integral ideals. This can be expressed as
+κ x
+qi
++ O(D
+1
+d+1+ε
+F
+(x/qi)
+d−1
+d+1+ε).
+21
+
+However, care has to be exercised. This is certainly true for x ≥ qi, however
+for x < qi the sum is empty and we have to check that
+κ x
+qi
+≪ D
+1
+d+1+ε
+F
+(x/qi)1−
+2
+d+1+ε
+(uniformly when d is fixed.) This reduces to
+κ ≪ D
+1
+d+1+ε
+F
+(x/qi)−
+2
+d+1+ε;
+but x/qi ≤ 1 and κ ≪ Dε
+F.
+Now return to the sum (3.7). By the inclusion–exclusion principle, it is
+equal to
+�
+Si −
+�
+Sij +
+�
+Sijk − · · ·
+where
+Sij···ℓ =
+�
+Na≤x
+qi···qℓ|a
+1.
+The same argument yields, with q = qi · · · qℓ, q = qi · · · qℓ:
+Sij···ℓ = κ x
+qi
++ O
+�
+D
+1
+d+1+ε
+F
+(x/q)
+d−1
+d+1+ε�
+.
+The previous argument remains correct for x ≤ q, with the same uniformity.
+Let us write ξ = d−1
+d+1 + ε. We now have
+(3.9)
+A0(x) =
+�
+i
+�
+1 − 1
+qi
+�
+κx + O(
+�
+(1 + q−ξ
+i )D
+1
+d+1+ε
+F
+xξ).
+In (3.9), we can (brutally) replace DF by D ≥ DF. We have to evaluate
+Q = �(1 − 1
+qi) and R = �(1 + q−ξ
+i ).
+Let pi be the prime divisor of qi. Then
+Q ≥
+�
+i
+�
+1 − 1
+pi
+�
+.
+There may be several primes associated to pi, but fewer than d = [F : Q].
+Thus
+Q ≥
+�
+j
+�
+1 − 1
+pj
+�d
+22
+
+where the pj are now distinct. But pj divides Nfχ, so pj ≤ N = Nfχ and
+Q ≥
+�
+p≤N
+�
+1 − 1
+p
+�d
+.
+Since �
+p≤N
+(1 − 1
+p) =
+e−γ
+log N (1 + O(
+1
+log N )) we deduce that Q ≥ A log(Nfχ)−d. (If
+χ is everywhere unramified, Q = 1.).
+Consider now R = �(1 + q−ξ
+i ). Again, R ≤ �
+i
+(1 + p−ξ
+i ) ≤ (�
+j
+(1 + p−ξ
+j ))d,
+with the same notation. But �(1 + p−ξ
+j ) = σ−ξ(p1 · · · pj) < σ0(p1 · · · pj) ≪
+(p1 · · · pj)ε ≪ (Nfχ)ε and the same estimate obtains for R.
+Now fix ν > 1 − 1
+d and consider the integral
+� β
+1
+|x−νA0(x)|2dx
+x .
+By (3.9) this is a sum of three terms, one of them exact:
+I1 =
+� β
+1
+(Qκx1−ν)2dx
+x ,
+so
+(3.10)
+I1 ≍ Q2κ2β2−2ν
+(β ≥ 2).
+The second term is dominated by
+I2 = D
+1
+d+1+εQκ
+� β
+1
+x2−
+2
+d+1−2ν dx
+x
+using that R ≪ Dε, so
+(3.11)
+I2 ≍ D
+1
+d+1+εQκβ2−
+2
+d+1−2ν.
+The third term is dominated by
+I3 = D
+2
+d+1+ε
+� β
+1
+x−2ν+1−
+4
+d+1+εdx
+(rescaling ε · · ·).
+23
+
+For ν > 1 − 1
+d, the exponent in the integral is always < −1 (Assume
+d > 1.) Thus
+(3.12)
+I3 ≍ D
+2
+d+1+ε.
+We now compare I1 and I2; we want to assume that I1 is dominant, i.e.
+Qκ ≻ D
+1
+d+1+εβ−
+2
+d+1.
+We now assume that the extension F/Q is Galois. By the Brauer–Siegel
+theorem, κ ≫ D−ε
+F , the implicit constant depending only on d.
+By our
+estimate on Q, we must have
+D−ε
+F (log Nfχ)−d ≻ D
+1
+d+1+εβ−
+2
+d+1
+which is true, upon changing ε, if
+β
+2
+d+1 ≻ D
+1
+d+1+ε,
+i.e.
+(3.13)
+β ≫ D
+1
+2+ε.
+Now consider I1 and I3. In this case, using again the estimate on Qκ, we
+must have
+β2−2ν ≻ D
+2
+d+1+ε;
+for ν close to 1 − 1
+d, we see that this yields
+(3.14)
+β ≫ D
+d
+d+1+ε.
+We now compare I1, assumed to be dominant, with the estimate given by
+Lemma 3.1. This yields
+D1−ν+ε ≫ Q2κ2β2−2ν;
+since we can neglict Q κ, we obtain
+β ≪ D1/2+ε.
+The conclusion is:
+β ≫ D
+d
+d+1+ε ⇒ β ≪ D1/2+ε.
+We conclude that β ≪ D
+d
+d+1+ε for large D.
+There is a finite number of
+pairs (F, χ) such that DFN(fχ) ≤ A. Indeed there is then a finite number of
+possibilities for F; for F fixed the primes and the ramification degrees of χ
+are bounded. Therefore:
+24
+
+Theorem 3.1. Consider the Galois extensions F of degree d ≥ 2 of Q, and
+the non–trivial Artin characters χ of F. Let β = Np where p is an unramified
+prime of smallest norm such that χ(p) ̸= 1. Then
+β ≪ D
+d
+d+1+ε
+where D = DFN(fχ) and the implicit constant depends only on d and ε.
+Remark.
+It may be possible to obtain a slightly better estimate, depending
+of Nfχ, by avoiding the change of DF to D after (3.9).
+3.4
+Now let F be a number field and
+ρ : Gal(E/F) −→ GL(M, C)
+an irreducible representation of degree M. We consider its Artin L–function
+L(s, ρ), given by an Euler product of degree M over F. We can view it as
+an L–function of degree m = Md over Q. We assume that ρ is non–trivial
+and that the Artin Conjecture is true for ρ : L(s, ρ) is holomorphic. (For a
+review of recent results on the Artin Conjecture see Calegari [Ca ] and the
+references therein.). We recall that the results of Friedlander–Iwaniec apply
+to L(s, ρ) (cf. [2, § 2.1].)
+The (absolute) conductor D of L(s, ρ) is equal to DM
+F N(fρ) where fρ, an
+ideal of F, is the Artin conductor of ρ, cf. Neukirch [16, Prop.11/7].
+Let L(s, ρ) =
+∞
+�
+1
+ann−s. Its Euler product (over F) is
+L(s, ρ) =
+�
+p
+det((1 − FrobpNp−s) | V Ip)−1
+where V is the space of ρ and Ip is the inertia. In particular, the ramified
+primes introduce factors �
+i
+(1 − αi,pNp−s)−1, where αi,p is a root of unity
+different from 1, that are not positive. In order to apply the method of § 3.2,
+we introduce the unramified L–function
+L(s, ρ) =
+�
+p
+Lp(s, ρ)
+25
+
+where the product ranges only over the unramified primes. Thus, with q
+ranging over the ramified primes,
+L(s, ρ) = L(s, ρ)
+�
+q
+Dq(s, ρ)
+where Dq(s, ρ) = �
+i
+(1 − αi,qNq−s). Let D(s, ρ) = �
+q
+Dq(s, ρ). We need to
+control
+the
+growth
+of
+L(s, ρ)
+in
+the
+critical
+strip.
+For
+Re(s) ≥ 0, Dq(s, ρ) ≤ 2M−1. Thus
+|D(s, ρ)| ≤ 2(M−1)r ≤ 2d(M−1)t
+where r is the number of ramified primes q and {p1, . . . pt} are the distinct
+rational primes dividing one of the qj.
+Fix d, and fix ε > 0. We first show that
+(3.15)
+|D(s, ρ)| ≤ (DM
+F Nfρ)ε
+except for a finite number of pairs (F, f). Assume first r → ∞. We have
+r ≤ dt, so t ≥ [ r
+d]. Moreover pi | Nfρ, so Nfρ ≥ � pi ≥ t! Thus (3.14) is
+verified if 2(M−1)r ≤ Γ([ r
+d] + 1)ε, thus if
+2M−1)r ≤
+�
+Γ
+�r
+d
+��ε
+.
+Since ε is fixed, this is true for large r by Stirling’s formula.
+So assume now r ≤ r0. Then |D(s, ρ)| ≤ 2(M−1)r0 and (3.15) is true if DF
+is large, i.e., excluding a finite number of F.
+Again, for F fixed, (3.15) is true if Nfρ is sufficiently large. If Nfρ ≤ A,
+this leaves a finite number of possibilities for the places and degrees of fρ.
+Finally (3.15) is violated only for a finite number of values of (F, fρ).
+Therefore we have
+|D(s, ρ)| ≤ A(DM
+F Nfρ)ε
+for a sufficiently large constant A. By Proposition 1.1, then:
+Lemma 3.2. For Re(s) ≥ 0,
+L(s, ρ) ≪ C(s)
+1−σ
+2 +ε
+where C(s) is the analytic conductor of L(s, ρ).
+26
+
+We can now imitate the arguments of §2. Let β be the smallest norm Np
+of an unramified prime such that ρ(Frobp) ̸= 1. If L(s, ρ) = �
+a
+b1(a)Na−s
+is the Dirichlet series of L(s, ρ) over F, the coefficients b1(a) coincide, for
+Na < β, with those of the Euler product (S = {q1, . . . , qs})
+LS(s, ρ)
+= �
+p/∈S
+(1 − Np−s)−M
+= (ζS
+F(s, ρ))M.
+These coefficients are equal to 0 if a is divisible by one of the qi, and ≥ 1
+otherwise. (Using the explicit series for (1 − X)−M does not lead to better
+estimates.). Thus, with q = � qj:
+(3.16)
+L(s, ρ) =
+∞
+�
+n=1
+bn n−s
+where
+(3.17)
+bn ≥
+�
+Na=n
+(a,q)=1
+1
+(n < β).
+Now let B0 be the summation function of L(s, ρ):
+B0(x) =
+�
+n≤x
+bn.
+For x < β, this is given by (3.16), and this has been analysed in § 3.3.
+(See formulas (3.6) to (3.9).) In fact, with A0(x) defined by (3.6), we now
+have
+Lemma 3.3. For x < β,
+B0(x) ≥ A0(x)
+where (for x < β)
+A0(x) = Qκx + O(RD
+1
+d+1+εx
+d−1
+d+1 +ε).
+Again, we have replaced DF by D; κ is the residue of ζF.
+However, we still have to check that the Mellin transform can be applied
+to yield the summation function B0(x), and for which values of s.
+27
+
+3.5
+We write simply D(s, ρ) = �
+j
+(1 − αjNq−s
+j ) where qj ranges over ramified
+primes and αj over the associated roots. Let qj = Nqj. With L(s, ρ) =
+�
+n
+a(n)n−s,
+L(s, ρ)(1 − αq−s) =
+�
+n≥1
+(a(n) − αa(n/q))n−s
+where αn/q = 0 if q ∤ n. We deduce that L(s, ρ) = �
+n
+bnn−s, where
+bn = a(n) − �
+j
+αja(n/qj) + �
+j1,j2
+αj1αj2a(n/qj1qj2)−
+· · · + (−1)Nα1 · · · αNa(n/q1 · · · qN),
+N being the degree of D(s, ρ); the same condition on a(n/q1 · · · qn) applies.
+Recall that m = dM. By the theorem of Friedlander–Iwaniec, we have
+A0(x) ≪ D
+1
+m+1 +εx
+m−1
+m+1 +ε
+(x ≥ 1)
+where A0 is the summation function for L(s, ρ), and we deduce that the same
+estimate is true for B0(x) if x is sufficiently large. In particular (Lemma 2.1)
+�
+MB0(s) is given by an absolutely convergent integral if Re(s) > 1 −
+2
+m+1,
+and, for ν = Re(s) > 1 − 1
+m,
+(3.18)
+�
+ν
+���L(s)
+s
+���
+2
+|ds| ≪ D1−ν+ε
+(See Lemma 3.1.)
+By Lemma 3.3, the integral
+� β
+1
+|x−νB0(x)|2dx
+x
+is larger than
+� β
+1
+|x−νA0(x)|2dx
+x
+where the expression of A0 is recalled in Lemma 3.3. We now imitate the
+calculation in § 3.3. We find first an explicit term, cf (3.10)
+I1 ≍ Q2κ2β2−2ν.
+28
+
+However, in the computation of I2, the exponent 2 −
+2
+d+1 − 2ν is negative
+for ν > 1 − 1
+m, so
+I2 ≪ D
+1
+d+1+εQκR.
+The same applies to the third term,
+I3 ≪ D
+2
+d+1+εR2.
+Note that Q, R and κ depend on F, not on ρ. However DF ≪ D, so we
+can use the estimates in § 3.3, and neglect these terms if F is Galois over Q.
+With ν ∼ 1 − 1
+m, we see that I1 dominates I2 if
+(3.19)
+β ≫ D
+m
+2(d+1) +ε,
+and that it dominates I3 if
+(3.20)
+β ≫ D
+m
+d+1+ε.
+Using (3.18) we see that
+β ≫ D
+m
+d+1+ε ⇒ β ≪ D1/2+ε.
+The conclusion, as in §3.3, is that
+β ≪ D
+m
+d+1+ε.
+Theorem 3.2. Let ρ : Gal(E/F) → GL(M, C) be an irreducible, non trivial
+representation and β = Np be the smallest norm of a prime p of F such that
+ρ(Frobp) ̸= 1. Then, if L(s, ρ) is holomorphic and F/Q Galois,
+β ≪ D
+m
+d+1+ε
+where d = [F : Q], m = Md, and D = DM
+F N(fρ).
+The implicit constant depends only on M and d, but it is not effective
+since we have used the Brauer–Siegel theorem.
+29
+
+3.6
+It is of course of interest to compare this result with earlier estimates. Assume
+E is minimal, i.e., ρ : Gal(E/F) → GL(M, C) is injective; let G = Gal(E/F)
+and g = |G|. If C is a conjugacy class in G, let P(C) be the set of primes p
+of F such that ρ is unramified at p and ρ(Frobq) ∈ C; let P1(C) be the subset
+composed of primes such that f(p/p) = 1; i.e. Np = p. Let β(C), β1(C)
+denote the smallest norm of elements in P(C), P1(C). Then the following
+results are known:
+(3.21)
+β(C) ≪ (log DE)2(log log DE)4
+(Lagarias and Odlyzko, 1975, under the generalized Riemann hypothesis)
+(3.22)
+β1(C) ≪ DA
+E
+(Lagarias, Montgomery and Odlyzko, 1979, unconditionaly) which has been
+improved by Zaman (2017) to
+(3.23)
+β1(C) ≪ D40
+E .
+In the last two results, the implicit constant is effective. See [10, 11, 20]. The
+last estimate has been improved to β1(C) ≤ D16
+E for large DE, see [9].
+Clearly β1(C) ≥ β(C) and β ≤ Inf
+C
+β(C), where C runs over non–trivial
+conjugacy classes. Since the estimates are uniform with respect to C, (3.20)–
+(3.22) give an upper bound for β. However,
+DE = Dg
+FNF/Q(dE/D),
+equal by the F¨uhrerdiskriminantenproduktformel to
+(3.24)
+Dg
+F
+�
+ρ
+(NF/Qfρ)dim ρ,
+to be compared with
+(3.25)
+D
+m
+d+1 = D
+M2
+d
+d+1
+F
+N(fρ)M
+d
+d+1,
+M = dim ρ. We have M2 < g, so the first factor of (3.25) is negligible with
+respect to that of (3.24). Similarly, since M = dim ρ, the second factor of
+30
+
+(3.25) is smaller that that of (3.24) relative to our chosen ρ. In general the
+new bound is much better. However, our argument applies only to fields F,
+and representations ρ, of bounded degrees d, M.
+A more pertinent comparison, however, is with Zaman’s paper [21], which
+gives an estimate for β (the smallest norm of a prime p of F that does not
+split in E; Zaman also assumes that p is of degree 1 over F. ) For simplicity
+we only consider the case where F = Q. In this case [21, Cor.1.2], with
+g = [E : Q], Zaman’s estimate is
+β ≪ D
+1+ε
+4A(g−1)
+E
+≪ (
+�
+ρ
+(Nfρ)dim ρ)
+1+ε
+4A(g−1)
+with A ≈ 1, to be compared with (this paper)
+β ≪ N(fρ0)M/2+ε, M = dim ρ0
+where ρ0 is our chosen representation. The comparison therefore depends
+on the complexity of the Galois group G, in particular its number of large
+representations and their ramification. For larger fields F [21, Theorem1.1],
+this is multiplied by a term at least of order exp(Ag(log DF)2) (here A is again
+an implicit constant) and the product will likely be larger that the estimate
+of Theorem 3.2. Note also that Zaman does not assume the extensions to be
+Galois.
+Example: Assume ρ is associated to a normalised newform f of weight
+1 on Γ0(q). Then fρ = (q) ⊂ Z, and Theorem 3.2 yields β ≪ q1+ε.
+4
+Complements to [2] and remarks on a pa-
+per of Friedlander–Iwanieˇc
+4.1
+The method of Friedlander–Iwanieˇc, and the proof in the Appendix of [2],
+use only the L–function of a (putative) representation π. In particular, they
+apply to the Rankin L–function L(s, π1 ⊠π2) of two cuspidal representations
+31
+
+of GL(m1, A) and GL(m2, A). In particular, we have:
+(4.1)
+The lower bounds on the quadratic integrals
+of L(s) in Theorems A − D of [2]are true
+if L(s) = L(s, π1 ⊠ π2), π1, π2 cuspidal.
+Assume moreover π1, π2 tempered, and π1,∞, π2,∞ self–dual. Let
+L(s, π1 ⊠ π2) = � ann−s and
+A(x) = �
+n≤x
+ann−s. Then
+(4.2)
+A(x) = κx + O(D
+1
+m+1x1−
+2
+m+1+ε)
+where m = m1m2, and κ is the usual residue, and D is the conductor of
+L(s, π1 × π2).
+The estimation of As(x) in [2, Thm. 2.2], also applies; for π1 ≇ ˜π2| |ia,
+this yields:
+(4.3)
+The abscissa of convergence of L(s, π1 ⊠ π2)
+satisfies σc ≤ 1 −
+2
+m+1.
+4.2
+However, the results of Chapter 2 on “short” integrals do not apply in general
+to Rankin L–functions. Indeed Molteni uses the properties of L(s, π ⊠ ˜π);
+for π = π1 ⊠ π2, this would assume the properties of the L–function of a
+quadruple tensor product.
+4.3
+In [2, §3.4] we discussed the relation between the exponent ν of an estimate
+of A0(x):
+A0(x) = O(xν+ε)
+where A0(x) is associated to a cuspidal π, and the convexity estimates. For
+simplicity we assume L(s, π) holomorphic. We have the relation
+� ∞
+1
+A0(x)x−sdx
+x = L(s)
+s
+32
+
+(Re(s) > ν). Suppose s = σ + it, σ > ν. This can be written as
+� ∞
+0
+A0(eX)e−σXe−itXdX.
+The function A0(eX)e−σX is exponentially decreasing, and therefore this
+Fourier transform is a C0 function of t; this implies that µ(σ) ≤ 1.
+The convexity estimate for µ(σ) is m
+2 (1 − σ). Thus µ(σ) ≤ 1 beats the
+convexity estimate if σ < 1 − 2
+m.
+Friedlander and Iwaniec have shown that the exponent ν = 1− 2
+m could be
+obtained for L(s) = L(s, π1)L(s, π2) and m = m1 + m2, m1, m2 ≥ 2. See [4,
+§3]2. We see that any improvement on ν = 1− 2
+m would lead to subconvexity
+(in the t–aspect) quite generally for GL(m) (and not only over Q.) 3 If we
+assume the optimum value conjectured by them, ν = 1
+2 −
+1
+2m, we obtain the
+following approximation of the Lindel¨of Conjecture:
+(4.4)
+µ(σ) ≤ m
+2 − m(m − 2)
+m − 1
+σ
+(σ ≤ 1
+2 − 1
+2m)
+(4.5)
+µ(σ) ≤
+2m
+m + 1(1 − σ)
+(σ ≥ 1
+2 − 1
+2m).
+The restriction to two factors is not one when subconvexity is concerned,
+because the estimate for L(s, π × π) implies one for L(s, π).
+References
+[1] Calegari, Frank The Artin conjecture for some S5-extensions. Math. Ann.
+356 (2013), no. 1, 191-207.
+[2] Clozel, Laurent A universal lower bound for certain integrals of automor-
+phic L-functions. With an appendix by L. Clozel and Peter Sarnak. arxiv:
+2203.12475.
+[3] Erd´elyi, Arthur;
+Magnus, Wilhelm;
+Oberhettinger, Fritz;
+Tricomi,
+Francesco G. Higher transcendental functions. Vol II. Based, in part, on
+notes left by Harry Bateman. McGraw-Hill Book Co., Inc., New York-
+Toronto-London, 1953.
+2They do not, however, give the proof. It has been explained to the author by Fried-
+lander and Brumley.
+3For GL(n) over Q this has been recently proved by Nelson [15]
+33
+
+[4] Friedlander, John B.; Iwaniec, Henryk Summation formulae for coeffi-
+cients of L-functions. Canad. J. Math. 57 (2005), no. 3, 494-505.
+[5] Harcos, Gergely Uniform approximate functional equation for principal
+L-functions. Int. Math. Res. Not. 2002, no. 18, 923-932.
+[6] Harcos, Gergely Erratum to: ”Uniform approximate functional equation
+for principal L-functions. ” Int. Math. Res. Not. 2004, no. 13, 659-660.
+[7] Iwaniec, Henryk; Kowalski, Emmanuel Analytic number theory. Ameri-
+can Mathematical Society Colloquium Publications, 53. American Math-
+ematical Society, Providence, RI, 2004.
+[8] Jacquet,
+H.;
+Piatetski-Shapiro,
+I. I.;
+Shalika,
+J. Conducteur des
+repr´esentations du groupe lin´eaire. Math. Ann. 256 (1981), no. 2, 199-
+214.
+[9] Kadiri, Habiba; Ng, Nathan; Wong, Peng-Jie The least prime ideal in the
+Chebotarev density theorem. Proc. Amer. Math. Soc. 147 (2019), no. 6,
+2289-2303.
+[10] Lagarias, J. C.; Odlyzko, A. M. Effective versions of the Chebotarev den-
+sity theorem. Algebraic number fields: L-functions and Galois properties
+(Proc. Sympos., Univ. Durham, Durham, 1975), pp. 409-464. Academic
+Press, London, 1977.
+[11] Lagarias, J. C.; Montgomery, H. L.; Odlyzko, A. M. A bound for the
+least prime ideal in the Chebotarev density theorem. Invent. Math. 54
+(1979), no. 3, 271-296.
+[12] Li, Xiannan Upper bounds on L-functions at the edge of the critical
+strip. Int. Math. Res. Not. IMRN 2010, no. 4, 727-755.
+[13] Luo, Wenzhi; Rudnick, Ze´ev; Sarnak, Peter On the generalized Ramanu-
+jan conjecture for GL(n). Automorphic forms, automorphic representa-
+tions, and arithmetic (Fort Worth, TX, 1996), 301-310, Proc. Sympos.
+Pure Math., 66, Part 2, Amer. Math. Soc., Providence, RI, 1999.
+[14] Molteni, Giuseppe Upper and lower bounds at s=1 for certain Dirichlet
+series with Euler product. Duke Math. J. 111 (2002), no. 1, 133-158.
+34
+
+[15] Nelson, Paul D., Bounds for standard L-functions. arxiv: 2109.15230.
+[16] Neukirch, J¨urgen Algebraische Zahlentheorie. Springer-Verlag, Berlin,
+1992. [English: Neukirch, J¨urgen Algebraic number theory. Translated
+from the 1992 German original and with a note by Norbert Schappacher.
+With a foreword by G. Harder. Grundlehren der mathematischen Wis-
+senschaften, 322. Springer-Verlag, Berlin, 1999.]
+[17] Petrow, Ian; Young, Matthew P. The Weyl bound for Dirichlet L-
+functions of cube-free conductor. Ann. of Math. (2) 192 (2020), no. 2,
+437-486.
+[18] Ramachandra, K. Fractional moments of the Riemann zeta-function.
+Acta Arith. 78 (1997), no. 3, 255-265.
+[19] Titchmarsh, E. C. Introduction to the theory of Fourier integrals. Third
+edition. Chelsea Publishing Co., New York, 1986.
+[20] Zaman, Asif Bounding the least prime ideal in the Chebotarev density
+theorem. Funct. Approx. Comment. Math. 57 (2017), no. 1, 115-142.
+[21] Zaman, Asif The least unramified prime which does not split completely.
+Forum Math. 30 (2018), no. 3, 651-661.
+Laurent Clozel
+Math´ematiques, Bˆatiment 307
+Universit´e Paris-Saclay
+91405 Orsay Cedex
+France
+35
+
diff --git a/wtAzT4oBgHgl3EQfQfse/content/tmp_files/load_file.txt b/wtAzT4oBgHgl3EQfQfse/content/tmp_files/load_file.txt
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@@ -0,0 +1,843 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf,len=842
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='01198v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='NT]  3 Jan 2023  New applications of the Mellin transform  to automorphic L–functions  Laurent Clozel  Introduction  In an earlier paper [2], and its Appendix, written with Peter Sarnak, we  have obtained universal lower bounds on certain quadratic integrals of auto-  morphic L–functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For instance, if π is a cuspidal unitary representation  of GL(m, AQ), and L(s) = L(s, π):  (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1)  � +∞  −∞  ���L(1/2 + it)  1/2 + it  ���  2  dt > π  2 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Cf [2, Theorem D].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In this article, we follow some questions that arose nat-  urally in this context.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The first one was suggested by a remark of Sarnak, according to which we  cannot have such universal bounds for short intervals, e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' for the integral  on [−1, 1] in (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' at least such cannot be obtained if m is allowed to vary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  See the Introduction to [2], § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The argument does not succeed if m is fixed;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' neither did the author suc-  ceed in finding, for m fixed, an absolute bound on a short interval.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This  remains an interesting problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In Chapter 2, we obtain a universal lower bound, for m fixed, for the  integral on an interval [−A log C, A log C] where C is the analytic conductor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Even then, we could not obtain a fixed lower bound.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Rather, we prove  that this integral is larger than c(log C)−1/2 where c > 0 is an absolute  constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This may not be optimal, but it is commensurable with the Lindel¨of  conjecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (We hope that an analytic number theorist familiar with the  use of the Mellin transform, as in the proof of the approximate functional  equation, will be able substantially to improve this result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') Moreover, we can  shift the ordinate and obtain a general result on an interval [X − T, X + T]  where X is arbitrary and T is of the order of log X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  See Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2,  1  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The proof relies on a theorem of Molteni [14], further improved  by Xiannan Li [12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In Chapter 3, we follow a lead from [2, §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' There we considered Vino-  gradov’s Conjecture on the order of the first quadratic non–residue and we  showed that it followed directly, via the Mellin transform, from the Lindel¨of  conjecture (including in the q–aspect) for the associated Dirichlet L–function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (This may have been well–known to experts).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  A similar problem is, given a non trivial representation ρ of a Galois group  Gal(E/F) of number fields, to determine “the” first prime p of F — i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' one  of smallest norm — where ρ is unramified and ρ(Frobp) ̸= 1, Frobp being a  Frobenius element.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The proof of [2] extends naturally.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have treated first  the case where ρ is a one–dimensional character, in Chapter 3, § 1–3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' See  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' When ρ is non–Abelian, the proof is more delicate and leads us  to introduce the unramified variant L(s, ρ) of the Artin L–function L(s, ρ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  See Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6, we show that our estimate is, in some cases, better that the known  unconditional estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (The relevant result here is the recent one of Zaman  [21]) However we have to assume that F is a Galois extension of Q and, more  crucially, that L(s, ρ) is holomorphic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Note that we do not have to assume  that ρ is associated to an automorphic representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In Chapter 4, we have reviewed some odds and ends concerning the results  and arguments of [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular we point out that they apply to Rankin L–  functions — not only to the standard L–functions of [2];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' and we develop the  remarks made in [2] about the relation between estimates on the summation  function A0(x) — see § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1— and subconvexity for L(s, π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Finally, in Chapter 1, we have recalled some “well–known” results con-  cerning the growth of L–functions in the critical strip, in term of the analytic  conductor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Fortunately we could rely on the very clear exposition of Har-  cos [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For the convenience of the reader, we also collect some formulas for  special functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We use notation standard in analytic number theory, in particular Lan-  dau’s symbols ≪, O( ), indexed when we want to specify the dependence of  the implicit constants.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We use f ≺ g (f, g positive functions) for f/g → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We use A for an absolute constant (in the context), not always the same in  different occurrences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Acknowledgement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='- I thank Farrell Brumley, Jesse Thorner and Asif Za-  man for providing useful references, and Peter Sarnak for suggesting that  2  my lower bounds should be compared with the well-known bound of Ra-  machandra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' I also thank the Fondation Simone et Cino del Duca for financial  support.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  1  Majorations and formulas  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1  In this preliminary chapter we have grouped together the majorations and  formulas which will be used in the text, and crucially in using an “absolute”  version, due to Molteni, of the Friedlander–Iwanieˇc estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We briefly  recall our set–up, which is that of [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We consider a unitary cuspidal rep-  resentation π of GL(m, A), or a product π = π1 × π2 × · · · × πr (parabolic  induction) of cuspidal representations πi of GL(mi, A), m = � mi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  L(s, π) =  r�  i=1  L(s, πi).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  is the standard L–function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The completed L–function  Λ(s, π) = Ds/2 L(s, π∞) L(s, π),  where D is the conductor, an integer ≥ 1, satisfies a functional equation  Λ(s, π) = ε(π)Λ(1 − s, ˜π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For details and a review of the other L–functions to which these theorems  apply, see [2, § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We do not assume, as we did in [2], that π∞ is self–dual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The functional  equation can than be written  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1)  L(1 − s, π) = ε(π)γ(s)L(s, ˜π)  with  γ(s) = (π−mD)s−1/2  c(˜π∞)Γ(s, ˜π∞)  c(π∞)Γ(1 − s, π∞)  and  Γ(s, π∞) =  m  �  j=1  Γ  �s + cj  2  �  3  with  Re(cj) ≥  1  m2 + 1 − 1  2  [13].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Following Iwanieˇc and Sarnak, we associate to π its conductor D = D(π)  and its analytic conductor  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2)  C = C(π) = D(π)  m  �  j=1  (2 + |cj|)  as well as  C(s) = C(π, s) = C(π) (1 + |s|)m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (There is a finer version of C(s) ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' cf [7, p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 95] for a discussion of this.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') We  will need uniform estimates, in terms of these data, for γ(s) and L(s, π) in a  strip Re(s) ∈] − ε, 1 + ε[.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2  We recall the known bounds on γ(s) and L(s).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For γ(s) a uniform bound  is derived by Harcos [5].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' See however the corrections in [6], in particular [6,  (3)] which corrects [5, 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='22]1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Lemma 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (Harcos) For σ > 1  m −  1  m2+1, Re(s) = σ,  γ(s) ≪  σ C(s)σ−1/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We now assume the Ramanujan conjecture for π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Fix ε > 0 (small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  Since πf is tempered, we have L(s, ˜π) ≪ 1 for Re(s) = 1 + ε, uniformly for  m fixed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For such a value of s, γ(s) ≪ C(s)1/2+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The functional equation  then implies  L(s, π) ≪ C(s)1/2+ε  for Re(s) = −ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We deduce from the Phragm´en–Lindel¨of principle:  Proposition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Assume πf tempered.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For −ε ≤ Re(s) ≤ 1 + ε,  L(s, π) ≪ε C(s)  1−σ  2 +ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Iwanieˇc–Kowalski [7, p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 100].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  1I thank Farrell Brumley for this reference.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  4  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3  Here we insert a few remarks on the analytic conductor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' It is not true that,  for A > 0 fixed, there exist a finite number of representations π such that  C(π) ≤ A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Indeed, if m = 1, and π = χ is a Dirichlet character of conductor  D, twisted by | |a, (a ∈ iR), the analytic conductor is D(2 + |a|).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  This  phenomenon persists in higher rank m, but is essentially due to the center  GL(1) of GL(m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Proposition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For any A > 0, there exist a finite number of cuspidal  representations π of GL(m, A) whose central character ω verifies ω|R×  + = 1  and such that C(π) < A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Since D(π) < C(π) there is a finite number of possibilities for D(π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let S  denote the connected component of 1 in the center Z(R) ∼= R× of GL(m, R).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Consider the space L = L2  cusp(S GL(m, Q)\\GL(m, A)) of L2–cusp forms in-  variant by S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The Hecke algebra �  v  Hv (where H∞ = C∞  c (GL(n, R)) and,  for v = p finite, Hp is the algebra of compactly supported smooth functions)  acts on L2  cusp by right translations, and it is well–known that this action is  trace–class.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Fix D ≥ 1, and let K(D) ⊂ GL(m, Af) be the congruence sub-  group defined by Jacquet, Piaterskii-Shapiro and Shalika [8, §5, Th´eor`eme],  and ϕD ∈ �  p  Hp its characteristic function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then ϕD projects L onto its  subspace composed of the K(D)–invariants in the cuspidal representations π  (with ωπ|R×  + = 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This is an infinite sum of representations ρ of GL(m, R);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  a function ϕ∞ ∈ C∞  c (GL(m, R)) acts on it by a trace–class operator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In par-  ticular, any compact subset of the unitary dual of GL(m, R) contains only a  finite number of such representations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' But the set of representations ρ such  that C∞(ρ) = �(2 + |cj|) ≤ A is compact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (See [2, § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2] for the relation  between the cj and the Langlands parameters of π∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  Assume again π cuspidal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For a ∈ i R, let π[a] = π ⊗ | det |a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We can  choose a such that π[a] has trivial central character on R×  +.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In view of this,  it is useful to know the relation between C(π) and C(π[a]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Again we refer to [2, § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The representation π∞ is associated to a sum  of real characters  ν(x) = (sgnx)ε|x|c  (x ∈ R×  +);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' ε = 0, 1)  5  and of characters of C×:  µ(z) = zp(¯z)q, p − q ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (The result of Luo–Rudnick–Sarnak [13] implies simple bounds on Re(c),  Re(p + q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  The datum cj associated to ν is c + ε;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' the data cj associated to µ are  (q, q + 1)  if  Re(p − q) < 0  (p, p + 1)  if  Re(p − q) > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  If we twist by | |a, the cj are transformed into cj + a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Therefore  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3)  C(π[a]) ≤ C(π)(1 + |a|)m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We also remark that if C(π) = 2m, D(π) = 1 and the cj are equal to 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Under this assumption, the number of π is therefore finite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Finally, it is of interest to know when ω|R×  + = 1 in terms of the cj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' However  the relation is not direct.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The real characters νj contribute cj = c + ε, where  νj(x) = xc, x > 0;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' A complex character µ(z) determines a representation π2  of GL(2, R) of central character xp+q (x > 0), and cj, cj′ equal to (q, q + 1)  or (p, p + 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' One checks that cj + cj′ = p + q + n where n = |p − q| > 0 is  the ramification of π2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Therefore the central character of π∞, on R×  +, is xA,  A =  �  cj − Ram(π∞),  where  Ram(π∞) =  �  ε +  �  n  is the ramification of π∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' To obtain a representation with ω|R×  + = 1, we have  to twist by | det|−A/m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The new conductor is (very roughly) bounded by  C(π)(1 + |A/m|)m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4  For the reader’s convenience we recall a few facts on special functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We  will use the functions  Erf(x)  =  � x  0  e−t2dt,  Erfc(x)  =  � ∞  x  e−t2dt = 1  2  √π − Erf(x).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  6  See [3, p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 147].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular we have the asymptotic expansion of Erfc(x)  for x ≫ 0:  Erfc(x) = 1  2e−x2(x−1 + O(x−3)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We will also need an estimate for  I(a, T) =  � ∞  T  e−t2tadt  (T > 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  This is best computed as an incomplete gamma function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' With  Γ(a, x)  =  � ∞  x  e−ttadt  t ,  I(a, T)  =  � ∞  T  e−t2ta+1dt  t  = 1  2  � ∞  T 2 e−ss  a+1  2 ds  s  = 1  2Γ  �a + 1  2  , T 2�  and the asymptotic expansion [3, p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 135]  Γ(a, x) = xa−1e−x(1 + O(1  x))  now yields  I(a, T) = 1  2T a−1e−T 2(1 + O(T −2)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  2  The quadratic integral of L(1/2+it)  1/2+it  on short  intervals  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1  In this section we assume m fixed;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' we consider π verifying the assumptions  in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We write  L(s)  = L(s, π),  L(s, π)  =  �  ann−s,  A0(x)  =  �  n≤x  an  (x ≥ 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  7  We assume given ξ, ν > 0 and consider only π such that ν ≥ σc(π) where  σc(π) is the abscissa of convergence of L(s, π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We assume that we have, for  x ≥ 1 and any ε, an estimate  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1)  A0(x) ≪ε Cξ xν+ε  where the implicit constant depends only on ε, and C = C(π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For a suitable  function f on R×  +, we define  �  Mf(s) =  � ∞  0  f(x)x−sdx  x .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' [2, § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3]) For Re(s) > ν, the integral defining �  MA0(s) is  absolutely convergent and �  MA0(s) = L(s)  s .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Indeed  � X  0  � �  n≤x  an  �  n−sdx  x  =  �  n≤X  an  � X  n  x−s−1dx  = 1  s  �  n≤X  ann−s − 1  s  � �  n≤X  an  �  X−s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Since Re(s) > σc(π), the first sum converges to L(s, π) for X → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The  second is dominated by Xν+ε/2X−ν−ε → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For σ > ν, we then have  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2)  � ∞  1  x−σA0(x)x−itdx  x = L(σ + it)  σ + it  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In order to obtain a minoration of the L2–norm of  L( 1  2 +it)  1/2+it on an interval  [−T, T], we consider its scalar product with a Gaussian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus let, for α > 0:  gα(t) = e−παt2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We extend gα to a function of s, equal to gα(t) for s = 1/2 + it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus  Gα(s) = eπα(s−1/2)2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  8  This is a function of rapid decrease in t (s = σ + it), uniformly in any  vertical strip.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular, for σ > ν:  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3)  �  σ  L(s)  s  Gα(s)ds = i  � +∞  −∞  L(1/2 + it)  1/2 + it  gα(t)dt  since L(s) and Gα(s) have no poles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We estimate the left–hand side using  the Fourier transform.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have by (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2)  � ∞  0  e−σXA0(eX)e−itXdX = L(σ + it)  σ + it  ,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  L(σ + it)  σ + it  = F(e−σXA0(eX))  where  Fh(t) =  � +∞  −∞  h(X)e−itXdX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The inverse transformation is  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4)  F −1k(X) = 1  2π  � +∞  −∞  k(t)eitXdt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The scalar product formula is  �  k1(X)k2(X)dX = 1  2π  �  h1(t)¯h2(t)dt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  However, (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3) is a bilinear product, and then:  �  h1(t)h2(t)dt = 2π  �  k1(X)k2(−X)dX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Therefore the left–hand side of (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3) is equal to the product of i = √−1 and  of  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='5)  2π  � ∞  0  e−σXA0(eX) ˆGα(−X)dX  where ˆGα(X) is given by (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4) applied to k(t) = Gα(σ + it).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Now  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6)  Gα(σ + it) = eπα(σ−1/2)2e−παt2e2πα(σ−1/2)it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  9  We have  F −1k(X) = 1  2πF −1  0 k( X  2π)  where F0, F −1  0  denote the usual Fourier transforms, normalised by 2π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Now  F −1  0 (f(t)e2iπβt)  = F −1  0 f(X + β),  F −1  0 (e−παt2)  =  1  √αe− π  αX2  so F −1  0 Gα)(X) is, by (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6), equal to  eπα(σ−1/2)2 1  √αe− π  α(X+α(σ−1/2))2  =  1  √αe− π  αX2e−2πX(σ−1/2),  and  F −1Gα(−X) =  1  2π√αe− X2  4πα e(σ−1/2)X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2  We now consider the integral (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='5), equal to  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='7)  1  √α  � ∞  0  e−σXA0(eX)e− X2  4πα e(σ−1/2)XdX  =  1  √α  � ∞  0  A0(eX)e− X2  4παe− X  2 dX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (It is, as it should be in view of the translation of complex integrals, inde-  pendent of σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  For 1 ≤ x ≤ 2, A0(x) = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We first obtain a lower bound for  I1 :=  1  √α  � log 2  0  e− X2  4παe− X  2 dX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In the sequel, Landau’s symbols O( ), ≪, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' , unindexed, are used when the  implicit constants are absolute.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have  I1 ≥  �  1/2 1  √α  � log 2  0  e− X2  4πα dX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  10  We set X =  √  4παY ;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' the integral is then  2√π  � log 2/2√πα  0  e−Y 2dY  =  2√πErf  � log 2  2√πα  �  =  2√π  �1  2  √π − Erfc  � log 2  2√πα  ��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For x → ∞, Erfc(x) =  1  2xe−x2(1 + O( 1  x2)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For small α, then,  I1 ≥ π  �  1/2 − O  �√α e− log2 2  4πα  �  and I1 ≥ π  2 := 2c for α sufficiently small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We now have to estimate the remainder, dominated by  I2 =  1  √α  � ∞  log 2  Cξ e(ν+ε−1/2)Xe− X2  4πα dX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Write θ = ν + ε − 1/2, and set  Y = X − 2πθα.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The exponential term in the integrand is then  exp  �  − Y 2  4πα  �  eπθ2α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We can neglect the constant since α will be small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus I2 is dominated by  I3  =  1  √α  � ∞  ℓ  Cξe−  1  4πα X2dX,  ℓ = log 2 − 2πθα.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  for small α, so the part relative to [ℓ, log 2] is dominated by Cξ√α · e−a1/α  with a1 > 0 fixed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We now consider  I4 = Cξ  � ∞  log 2  1  √αe−  1  4πα X2dX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  11  The integral is equal to 2√π Erfc( log 2  2√πα) (see the formulas in § 1);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' it  admits an expression  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='8)  √π e− log2 2  4πα  �2√πα  log 2 + O(α3/2)  �  for small α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This (multiplied by Cξ) is of the same order as the integral  on the small segment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We want to ensure that this is dominated by I1, which is implied by  √α e− a2  α Cξ ≤ a3  where a3 is a small constant, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  1  2 log α − a2  α + ξ log C ≤ −a4  (a4 > 0).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We may assume α ≤ 1, so we seek  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9)  a2  α ≥ a4 + ξ log C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Since C ≥ 2m, ξ log C > a5 > 0 and  1  a4 + ξ log C >  1  Nξ log C  for N such that a4 < (N − 1)ξ log C, so N is determined by constants inde-  pendent of π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Thus (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9) is verified if  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='10)  α ≤  a5  log C .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We summarise the result  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Assume π cuspidal, and σc(π) ≤ ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' There exist positive  constants c, b1 (depending only on ξ, ν) such that if C = C(π) and  α ≤  b1  log C ,  then  ���  � +∞  −∞  L(1/2 + it, π)  1/2 + it  gα(t)dt  ��� ≥ c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  12  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3  We can now apply the previous proof by using a theorem of Molteni [14].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (Molteni).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Assume π is a cuspidal, unitary representation of  GL(m, A).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  �  n≤x  |an| = Oε(Cεx1+ε)  (x ≥ 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (The implicit constant depends only on m and ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') In fact Molteni proves a  stronger result:  �  n≤x  |an|  n  = O(Cεxε).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Thus, in the previous proof, we may take ν = 1, ξ = ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (This has been  improved by Xiannan Li [12];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' the improved estimate seems irrelevant to  us, but the theorem extends to automorphic representations satisfying the  conditions in §1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1) The assumption σc(π) ≤ ν is of course satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We have given an exposition of the proof valid for other exponents, be-  cause of the following fact.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Consider only representations π that are tem-  pered, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' satisfy the Ramanujan Conjecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Assume moreover π∞ self–  dual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then by a result of Friedlander and Iwanieˇc, (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1) is satisfied with  ξ =  1  m+1, ν = m−1  m+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (See [4];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' the self–duality condition is implicit there, and  made explicit in [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') However Friedlander and Iwanieˇc consider only the  arithmetic conductor, so (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1) is replaced by  A0(x) ≪ D  1  m+1x  m−1  m+1 +ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  They must also assume that π∞ is bounded, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  C∞(π) = �(2 + |ci|)  bounded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Their estimate with respect to x is better, but this does not seem  to play any role in the present proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The fact that these representations π verify σc(π) ≤ m−1  m+1 is proved in [2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We will unfortunately have to assume the Ramanujan conjecture in the  next paragraph.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  13  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4  In order to exploit Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1 to obtain a lower bound on a “short”  interval, we must now estimate the tail  I5(T) =  � ∞  T  L(1/2 + it)  1/2 + it  gα(t)dt  (and the opposite one).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In order to have uniform estimates, we must now  assume that π verifies the Ramanujan Conjecture.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We now have  L(1  2 + it) ≪ C(t)  1  4 +ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Fix gα(t) = e−παt2 with α =  b1  log C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For T ≥ 1,  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='11)  I5(T) ≪ C  1  4+ε  � ∞  T  e−παt2t  m  4 −1+εdt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We need an estimate for  � ∞  T  e−παt2tadt;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  as recalled in Chapter 1,  � ∞  T  e−παt2tadt = 1  2π−1α−1T a−1e−παT 2· �  1 + O  � 1  παT −2��  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We want to ensure that |I5(T)| ≤ 1  4c;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  C  1  4+εα−1T a−1e−παT 2�  1 + O  � 1  αT −2��  ≪ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We assume provisionally that T can be chosen such that 1  αT −2 is small.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  this is implied by  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='12)  1  2 log C − log α + (a − 1) log T − παT 2 ≤ −X  where X is a positive constant;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' here a = m  4 − 1 + ε;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' we replace a by a value  such that a − 1 > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' With α =  b1  log C, we want to ensure  παT 2 − a log T ≥ X − log α + 1  2 log C,  14  which yelds  πb1T 2 − a log C log T ≥ log C(X′ + log log C + 1  2 log C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Assume T 2 = A1 log2 C for a large positive constant.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The left–hand side is  then  πb1A1 log2 C − a log C(log log C + log  �  A1) ≥ A2 log2 C  for A1 sufficiently large and C ≥ 2m, and this dominates the right–hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Moreover, 1  αT −2 ≪ (log C)−1A−2  1  ≤ 1  2 for A1 sufficiently large (independently  of C), as assumed previously.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Therefore:  Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For T = A log C, where A is a sufficiently large positive con-  stant, and α =  b1  log C,  ���  �  |t|≥T  L(1/2 + it)  1/2 + it  gα(t)dt  ��� ≤ c  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Now the absolute value of the integral for |t| ≤ T is ≥ c  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='13)  Sup  t∈[−T,T]  ���L(1/2 + it)  1/2 + it  ��� ≥ c  2  ���  �  t≤T  gα(t)dt  ���  −1  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='14)  ���L(1/2 + it)  1/2 + it  ���  2  ���gα(t)  ���  2 ≥ c  2  where the L2–norms are computed in [−T, T].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We now have to estimate the integral, and quadratic integral, of gα(t) on  [−T, T].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have  � T  0  e−παt2dt  =  � √παT  0  e−s2(√πα)−1ds  = a6(log C)1/2  � a7(log C)1/2  0  e−s2ds  ≍ (log C)1/2  and the same estimate is true for the quadratic integral.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Therefore we obtain  15  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' There exist absolute, positive constants A, c1, c2 such that  for any cuspidal π verifying the Ramanujan Conjecture  (i)  Sup  t∈[−T,T]  ���L(1/2 + it), π  1/2 + it  ��� ≥ c1(log C)−1/2  (ii)  � T  −T  ���L(1/2 + it), π  1/2 + it  ���  2  dt ≥ c2(log C)−1/2  if T ≥ A log C, C = C(π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  It may be noticed that in (i) the Lindel¨of Conjecture yields an estimate  ≪ (log C)ε (for T of order A log C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We have used the cuspidality of π only in order to rely on Molteni’s result;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Xianan Li’s result makes this unnecessary.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We can now use the remarks in §1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3 on the translation of integrals to  obtain lower bounds on L( 1  2+it, π) on short intervals, not necessarily centered  in 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have  L(s, π[X] = L(s + iX, π)  C(π[X]) ≤ C(π)(1 + |X|)m  log C(π[X]) ≤ log C(π) + m log(1 + |X|).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Let  S =  Sup  t∈[−T,T]  ���L(1/2 + it, π[X])  1/2 + it  ���.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  By Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2, for T ≥ A log C(π[X]):  S ≥ c1(log C + m log(1 + |X|))−1/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  However  S =  Sup  t∈[−T,T]  ���L(1/2 + i(t + X), π  1/2 + it  ��� ≤ 2 Sup  t∈[−T,T]  |L(1/2 + i(t + X, π)|  Thus we have the following result on “short intervals”.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' There exist absolute, positive constants A, c3, c4 > 0 such  that for any cuspidal π verifying the Ramanujan Conjecture  (i)  Sup  t∈[X−T,X+T]  |L(1/2 + it, π)| ≥ c3 · (log C(π) + m log(1 + |X|))−1/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  16  (ii)  � X+T  X−T  ��� L(1/2 + it, π  1/2 + i(t − X)  ���  2  dt ≥ c4(log C(π) + m log(1 + |X|))−1/2  if T ≥ A(log C + log(1 + |X|), C = C(π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The absolute constants depend only on m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Sarnak suggested that the estimate (ii) should be compared with the lower  bound on short intervals obtained by Ramachandra in [18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (Ramachandra  notes that his proof, written for the Riemann zeta function, will extend to  L-functions with Euler products.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' See [18, Remark 3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') In fact, because of  the large denominator in the integral, our lower bound seems better than  the one that follows obviously from Ramachandra’s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We assume X positive  and large and T small with respect to X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (In the next lines the constant A  depends on the formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') Then Ramachandra’s estimate is  � X+T  X  |L(1/2 + it)|2dt ≥ AT log T, T ≥ A log log X  while here we obtain  � X+T  X−T  ��� L(1/2 + it, π  1/2 + i(t − X)(  ���  2  dt ≥ A(log C + log X)−1/2  for T ≥ A(log C + log X).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For fixed C, our condition on T implies Ramachandra’s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We consider  T ≈ A log X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The denominator in our formula is smaller than T 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus  Ramachandra’s bound implies for the integral  � X+T  X−T  ��� L(1/2 + it, π  1/2 + i(t − X)  ���  2  dt  a lower bound in AT −1 log T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' But for T ≈ A log X, (log X)−1 log log X is  dominated by our bound (log X)−1/2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus, for fixed C, the results do not  seem commensurable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (It would be interesting to know how the conductor  enters in Ramachandra’s formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  17  3  The first non–trivial Frobenius element in  a Galois representation  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1  In this chapter we consider a non–trivial, irreducible representation ρ :  Gal(E/F) → GL(m, C), where E/F is a Galois extension of number fields.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  If ρ is unramified at a prime p of F, we can consider the image ρ(Frobp), a  conjugacy class in GL(m, C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We want to obtain a lower bound β on the  first value of Np such that ρ is unramified and ρ(Frobp) ̸= 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Of course, this  is complicated by the presence of ramification, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', there may be a ramified  prime q such that Nq ≤ β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' If m = 1, this applies to Artin characters of A×  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2  We first consider the Abelian case, m = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  If F = Q, we are looking  at primitive Dirichlet characters  mod q = D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' If L(s, χ) ≪ (q|s|)µ+ε for  Re(s) =  1  2, it was shown in [2, § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3] that β ≪ q2µ+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Since Petrow and  Young [17] have proved the Weyl bound µ ≤  1  6, we obtain by this simple  application of the Mellin transform  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1)  For χ a primitive Dirichlet character  mod q, β(x) ≪  ε q1/3+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Of course this is much weaker than Burgess’s bound (for q prime)  β(χ) ≪  ε q  1  4√e+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  However, we can now extend the method to Artin characters of A×  F for an  arbitrary number field F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  So let χ be a character of finite order, and ρ the 1–dimensional represen-  tation of Gal(Fχ/F) associated to χ by class field theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We consider the  L–function L(s, χ) as a L–function over Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' All the conditions in the paper of  Friedlander–Iwaniec are met — this will also be the case for a Galois repre-  sentation of degree > 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We therefore have the properties of L(s, χ) recalled  in § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Rather than the formulas in [2], we use the Mellin transform as in § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  18  Thus let  L(s, χ)  =  �  n  ann−s,  A0(x)  =  �  n≤x  an  and  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2)  �  M A0(x) =  � ∞  1  A0(x)x−s dx  x .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Let ν0 be the exponent of Friedlander–Iwaniec:  ν0 = d − 1  d + 1, d = [F : Q].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  so  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3)  A0(x)≪  d,εD  1  d+1xν0+ε  (x ≥ 1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We note that the Archimedean data (cj) associated to χ are uniformly  bounded, so the constant depends only on (d, ε).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Moreover (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2) is obtained  by Friedlander–Iwaniec for x ≥ D1/2 (see a correction in [2, § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='5]) but it is  trivial for x ≤ D1/2 since |an| ≪ nε′ for any ε′ > o.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The integral in (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2) is absolutely convergent for Re(s) > ν0, say Re(s) =  ν > ν0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The function A0(x)x−ν then belongs to L2(R×  +, dx  x ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' It follows (cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Titchmarsh [19]) that L(s)  s  is L2 on the line Re(s) = ν, and that  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4)  � ∞  1  |x−νA0(x)|2dx  x = 1  2π  �  ν  ���L(s)  s  ���  2  |ds|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  However, if ν is close to ν0, the convergence of the right–hand side does not  follow from convexity: see [2, § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' we will review this in Chapter 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' As a  consequence we cannot use Proposition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1 to estimate the right–hand side.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  By Proposition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1, we have µ(ν) ≤ d  2(1 − ν), so µ(ν) < 1  2 if ν > 1 − 1  d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The convergence of the right–hand side then follows from convexity and we  have again by Proposition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1:  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For ν > 1 − 1  d,  �  ν  ���L(s)  s  ���  2  |ds| ≪ D1−ν+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  19  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3  We now want to obtain a lower bound for the left–hand side of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We  consider the integral on [1, β] where β is the norm of the first unramified  prime such that χ(p) ̸= 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Before doing so we recall the expression of the “absolute” conductor D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Let DF be the absolute value of the discriminant of F;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' let f(χ) be the con-  ductor of χ (seen as a character of A×  F), an ideal of F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='5)  D = DF NF/Qf(χ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We need an expression for A0(x), for x < β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' It is then given by  an =  �  Na=n  a(a)  where � a(a)Na−s is the expression of L(s, χ) as an L–function over F, and  Na < β, which implies that the factorization of a involves only primes p with  Np < β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have  Lp(s, χ) = (1 − Np−s)−1  if χ is unramified at p and Np < β,  Lq(s, χ) = 1  is χ is ramified at q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' If a = � qαi  i  � p  βj  j (where we use {qi} to denote all the  ramified primes), this implies that  a(a) = 0  if αi > 0 for some i, and a(a) = 1 otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus, up to x = β, A0(x) is a  variant of the summation function for ζF:  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6)  A0(x) =  �  n≤x  �  Na=n  (qi,a)=1  1  where the condition (qi, a) = 1 is imposed for all i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let B0(x) be the sum-  mation function for ζF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The difference B0 − A0 is then  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='7)  �  n≤x  �  Na=n  ′1  20  where �′ is restricted by the condition  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='8)  ∃ i : qi|a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  At this point it is necessary to extend the main result of [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Very generally,  assume π is a tempered representation of GL(m, A);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' assume π is a product  π1 ×· · · πr of cuspidal representations (with at most a factor mi = 1, πi = 1);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  assume π∞ self-dual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let A0(x) be the associated summation function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let  κ be the residue of L(s, π) at 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We write D for the conductor of π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Proposition 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For x ≥ 1,  A0(x) = κx + O(D  1  m+1 +εx  m−1  m+1 +ε)  where the implicit constant depends only on m, ε and the Archimedean pa-  rameters of π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For the function ζF, the implicit constant depends only on d and ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For x ≥ D1/2 this is the result of [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For x ≤ D1/2, it was already noticed  in § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2 that A0(x) ≪ D  1  m+1x  m−1  m+1 +ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (This does not depend on the fact that  L(s) is holomorphic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') If x ≤ D1/2, D  1  m+1x−  2  m+1 ≥ 1 and it suffices to check:  κ ≪ (Dx)ε  which is true since κ ≪ Dε, cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' [7, p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 100].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (For a zˆeta function, this is the  easy part of the Brauer–Siegel theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  We can now apply this to B0:  B0(x) = κx + O(D  1  d+1+ε  F  x  d−1  d+1+ε),  κ = Ress=1ζF(s).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Now fix i and consider the sum (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='7), the condition being  qi|a.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' By a change of variables,  �  Na≤x  qi|a  1 =  �  Nb≤ x  qi  1  where qi = Nqi and b ranges over integral ideals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This can be expressed as  κ x  qi  + O(D  1  d+1+ε  F  (x/qi)  d−1  d+1+ε).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  21  However, care has to be exercised.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This is certainly true for x ≥ qi, however  for x < qi the sum is empty and we have to check that  κ x  qi  ≪ D  1  d+1+ε  F  (x/qi)1−  2  d+1+ε  (uniformly when d is fixed.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') This reduces to  κ ≪ D  1  d+1+ε  F  (x/qi)−  2  d+1+ε;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  but x/qi ≤ 1 and κ ≪ Dε  F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Now return to the sum (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' By the inclusion–exclusion principle, it is  equal to  �  Si −  �  Sij +  �  Sijk − · · ·  where  Sij···ℓ =  �  Na≤x  qi···qℓ|a  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The same argument yields, with q = qi · · · qℓ, q = qi · · · qℓ:  Sij···ℓ = κ x  qi  + O  �  D  1  d+1+ε  F  (x/q)  d−1  d+1+ε�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The previous argument remains correct for x ≤ q, with the same uniformity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Let us write ξ = d−1  d+1 + ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We now have  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9)  A0(x) =  �  i  �  1 − 1  qi  �  κx + O(  �  (1 + q−ξ  i )D  1  d+1+ε  F  xξ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9), we can (brutally) replace DF by D ≥ DF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have to evaluate  Q = �(1 − 1  qi) and R = �(1 + q−ξ  i ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Let pi be the prime divisor of qi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  Q ≥  �  i  �  1 − 1  pi  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  There may be several primes associated to pi, but fewer than d = [F : Q].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Thus  Q ≥  �  j  �  1 − 1  pj  �d  22  where the pj are now distinct.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' But pj divides Nfχ, so pj ≤ N = Nfχ and  Q ≥  �  p≤N  �  1 − 1  p  �d  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Since �  p≤N  (1 − 1  p) =  e−γ  log N (1 + O(  1  log N )) we deduce that Q ≥ A log(Nfχ)−d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (If  χ is everywhere unramified, Q = 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Consider now R = �(1 + q−ξ  i ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Again, R ≤ �  i  (1 + p−ξ  i ) ≤ (�  j  (1 + p−ξ  j ))d,  with the same notation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' But �(1 + p−ξ  j ) = σ−ξ(p1 · · · pj) < σ0(p1 · · · pj) ≪  (p1 · · · pj)ε ≪ (Nfχ)ε and the same estimate obtains for R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Now fix ν > 1 − 1  d and consider the integral  � β  1  |x−νA0(x)|2dx  x .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  By (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9) this is a sum of three terms, one of them exact:  I1 =  � β  1  (Qκx1−ν)2dx  x ,  so  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='10)  I1 ≍ Q2κ2β2−2ν  (β ≥ 2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The second term is dominated by  I2 = D  1  d+1+εQκ  � β  1  x2−  2  d+1−2ν dx  x  using that R ≪ Dε, so  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='11)  I2 ≍ D  1  d+1+εQκβ2−  2  d+1−2ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The third term is dominated by  I3 = D  2  d+1+ε  � β  1  x−2ν+1−  4  d+1+εdx  (rescaling ε · · ·).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  23  For ν > 1 − 1  d, the exponent in the integral is always < −1 (Assume  d > 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') Thus  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='12)  I3 ≍ D  2  d+1+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We now compare I1 and I2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' we want to assume that I1 is dominant, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Qκ ≻ D  1  d+1+εβ−  2  d+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We now assume that the extension F/Q is Galois.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' By the Brauer–Siegel  theorem, κ ≫ D−ε  F , the implicit constant depending only on d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  By our  estimate on Q, we must have  D−ε  F (log Nfχ)−d ≻ D  1  d+1+εβ−  2  d+1  which is true, upon changing ε, if  β  2  d+1 ≻ D  1  d+1+ε,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='13)  β ≫ D  1  2+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Now consider I1 and I3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In this case, using again the estimate on Qκ, we  must have  β2−2ν ≻ D  2  d+1+ε;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  for ν close to 1 − 1  d, we see that this yields  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='14)  β ≫ D  d  d+1+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We now compare I1, assumed to be dominant, with the estimate given by  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This yields  D1−ν+ε ≫ Q2κ2β2−2ν;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  since we can neglict Q κ, we obtain  β ≪ D1/2+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The conclusion is:  β ≫ D  d  d+1+ε ⇒ β ≪ D1/2+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  We conclude that β ≪ D  d  d+1+ε for large D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  There is a finite number of  pairs (F, χ) such that DFN(fχ) ≤ A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Indeed there is then a finite number of  possibilities for F;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' for F fixed the primes and the ramification degrees of χ  are bounded.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Therefore:  24  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Consider the Galois extensions F of degree d ≥ 2 of Q, and  the non–trivial Artin characters χ of F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let β = Np where p is an unramified  prime of smallest norm such that χ(p) ̸= 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  β ≪ D  d  d+1+ε  where D = DFN(fχ) and the implicit constant depends only on d and ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Remark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  It may be possible to obtain a slightly better estimate, depending  of Nfχ, by avoiding the change of DF to D after (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4  Now let F be a number field and  ρ : Gal(E/F) −→ GL(M, C)  an irreducible representation of degree M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We consider its Artin L–function  L(s, ρ), given by an Euler product of degree M over F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We can view it as  an L–function of degree m = Md over Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We assume that ρ is non–trivial  and that the Artin Conjecture is true for ρ : L(s, ρ) is holomorphic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (For a  review of recent results on the Artin Conjecture see Calegari [Ca ] and the  references therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=').' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We recall that the results of Friedlander–Iwaniec apply  to L(s, ρ) (cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' [2, § 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  The (absolute) conductor D of L(s, ρ) is equal to DM  F N(fρ) where fρ, an  ideal of F, is the Artin conductor of ρ, cf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Neukirch [16, Prop.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='11/7].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Let L(s, ρ) =  ∞  �  1  ann−s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Its Euler product (over F) is  L(s, ρ) =  �  p  det((1 − FrobpNp−s) | V Ip)−1  where V is the space of ρ and Ip is the inertia.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular, the ramified  primes introduce factors �  i  (1 − αi,pNp−s)−1, where αi,p is a root of unity  different from 1, that are not positive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In order to apply the method of § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2,  we introduce the unramified L–function  L(s, ρ) =  �  p  Lp(s, ρ)  25  where the product ranges only over the unramified primes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus, with q  ranging over the ramified primes,  L(s, ρ) = L(s, ρ)  �  q  Dq(s, ρ)  where Dq(s, ρ) = �  i  (1 − αi,qNq−s).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let D(s, ρ) = �  q  Dq(s, ρ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We need to  control  the  growth  of  L(s, ρ)  in  the  critical  strip.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For  Re(s) ≥ 0, Dq(s, ρ) ≤ 2M−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus  |D(s, ρ)| ≤ 2(M−1)r ≤ 2d(M−1)t  where r is the number of ramified primes q and {p1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' pt} are the distinct  rational primes dividing one of the qj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Fix d, and fix ε > 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We first show that  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='15)  |D(s, ρ)| ≤ (DM  F Nfρ)ε  except for a finite number of pairs (F, f).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Assume first r → ∞.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have  r ≤ dt, so t ≥ [ r  d].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Moreover pi | Nfρ, so Nfρ ≥ � pi ≥ t!' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='14) is  verified if 2(M−1)r ≤ Γ([ r  d] + 1)ε, thus if  2M−1)r ≤  �  Γ  �r  d  ��ε  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Since ε is fixed, this is true for large r by Stirling’s formula.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  So assume now r ≤ r0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then |D(s, ρ)| ≤ 2(M−1)r0 and (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='15) is true if DF  is large, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', excluding a finite number of F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Again, for F fixed, (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='15) is true if Nfρ is sufficiently large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' If Nfρ ≤ A,  this leaves a finite number of possibilities for the places and degrees of fρ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Finally (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='15) is violated only for a finite number of values of (F, fρ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Therefore we have  |D(s, ρ)| ≤ A(DM  F Nfρ)ε  for a sufficiently large constant A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' By Proposition 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1, then:  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For Re(s) ≥ 0,  L(s, ρ) ≪ C(s)  1−σ  2 +ε  where C(s) is the analytic conductor of L(s, ρ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  26  We can now imitate the arguments of §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let β be the smallest norm Np  of an unramified prime such that ρ(Frobp) ̸= 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' If L(s, ρ) = �  a  b1(a)Na−s  is the Dirichlet series of L(s, ρ) over F, the coefficients b1(a) coincide, for  Na < β, with those of the Euler product (S = {q1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' , qs})  LS(s, ρ)  = �  p/∈S  (1 − Np−s)−M  = (ζS  F(s, ρ))M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  These coefficients are equal to 0 if a is divisible by one of the qi, and ≥ 1  otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (Using the explicit series for (1 − X)−M does not lead to better  estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=').' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus, with q = � qj:  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='16)  L(s, ρ) =  ∞  �  n=1  bn n−s  where  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='17)  bn ≥  �  Na=n  (a,q)=1  1  (n < β).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Now let B0 be the summation function of L(s, ρ):  B0(x) =  �  n≤x  bn.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  For x < β, this is given by (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='16), and this has been analysed in § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  (See formulas (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6) to (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') In fact, with A0(x) defined by (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6), we now  have  Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For x < β,  B0(x) ≥ A0(x)  where (for x < β)  A0(x) = Qκx + O(RD  1  d+1+εx  d−1  d+1 +ε).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Again, we have replaced DF by D;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' κ is the residue of ζF.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  However, we still have to check that the Mellin transform can be applied  to yield the summation function B0(x), and for which values of s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  27  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='5  We write simply D(s, ρ) = �  j  (1 − αjNq−s  j ) where qj ranges over ramified  primes and αj over the associated roots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let qj = Nqj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' With L(s, ρ) =  �  n  a(n)n−s,  L(s, ρ)(1 − αq−s) =  �  n≥1  (a(n) − αa(n/q))n−s  where αn/q = 0 if q ∤ n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We deduce that L(s, ρ) = �  n  bnn−s, where  bn = a(n) − �  j  αja(n/qj) + �  j1,j2  αj1αj2a(n/qj1qj2)−  · · + (−1)Nα1 · · · αNa(n/q1 · · · qN),  N being the degree of D(s, ρ);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' the same condition on a(n/q1 · · · qn) applies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Recall that m = dM.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' By the theorem of Friedlander–Iwaniec, we have  A0(x) ≪ D  1  m+1 +εx  m−1  m+1 +ε  (x ≥ 1)  where A0 is the summation function for L(s, ρ), and we deduce that the same  estimate is true for B0(x) if x is sufficiently large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular (Lemma 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1)  �  MB0(s) is given by an absolutely convergent integral if Re(s) > 1 −  2  m+1,  and, for ν = Re(s) > 1 − 1  m,  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='18)  �  ν  ���L(s)  s  ���  2  |ds| ≪ D1−ν+ε  (See Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=')  By Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3, the integral  � β  1  |x−νB0(x)|2dx  x  is larger than  � β  1  |x−νA0(x)|2dx  x  where the expression of A0 is recalled in Lemma 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We now imitate the  calculation in § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We find first an explicit term, cf (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='10)  I1 ≍ Q2κ2β2−2ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  28  However, in the computation of I2, the exponent 2 −  2  d+1 − 2ν is negative  for ν > 1 − 1  m, so  I2 ≪ D  1  d+1+εQκR.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The same applies to the third term,  I3 ≪ D  2  d+1+εR2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Note that Q, R and κ depend on F, not on ρ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' However DF ≪ D, so we  can use the estimates in § 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3, and neglect these terms if F is Galois over Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  With ν ∼ 1 − 1  m, we see that I1 dominates I2 if  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='19)  β ≫ D  m  2(d+1) +ε,  and that it dominates I3 if  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='20)  β ≫ D  m  d+1+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Using (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='18) we see that  β ≫ D  m  d+1+ε ⇒ β ≪ D1/2+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The conclusion, as in §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3, is that  β ≪ D  m  d+1+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let ρ : Gal(E/F) → GL(M, C) be an irreducible, non trivial  representation and β = Np be the smallest norm of a prime p of F such that  ρ(Frobp) ̸= 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then, if L(s, ρ) is holomorphic and F/Q Galois,  β ≪ D  m  d+1+ε  where d = [F : Q], m = Md, and D = DM  F N(fρ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The implicit constant depends only on M and d, but it is not effective  since we have used the Brauer–Siegel theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  29  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='6  It is of course of interest to compare this result with earlier estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Assume  E is minimal, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', ρ : Gal(E/F) → GL(M, C) is injective;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' let G = Gal(E/F)  and g = |G|.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' If C is a conjugacy class in G, let P(C) be the set of primes p  of F such that ρ is unramified at p and ρ(Frobq) ∈ C;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' let P1(C) be the subset  composed of primes such that f(p/p) = 1;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Np = p.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let β(C), β1(C)  denote the smallest norm of elements in P(C), P1(C).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then the following  results are known:  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='21)  β(C) ≪ (log DE)2(log log DE)4  (Lagarias and Odlyzko, 1975, under the generalized Riemann hypothesis)  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='22)  β1(C) ≪ DA  E  (Lagarias, Montgomery and Odlyzko, 1979, unconditionaly) which has been  improved by Zaman (2017) to  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='23)  β1(C) ≪ D40  E .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  In the last two results, the implicit constant is effective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' See [10, 11, 20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The  last estimate has been improved to β1(C) ≤ D16  E for large DE, see [9].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Clearly β1(C) ≥ β(C) and β ≤ Inf  C  β(C), where C runs over non–trivial  conjugacy classes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Since the estimates are uniform with respect to C, (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='20)–  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='22) give an upper bound for β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' However,  DE = Dg  FNF/Q(dE/D),  equal by the F¨uhrerdiskriminantenproduktformel to  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='24)  Dg  F  �  ρ  (NF/Qfρ)dim ρ,  to be compared with  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='25)  D  m  d+1 = D  M2  d  d+1  F  N(fρ)M  d  d+1,  M = dim ρ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have M2 < g, so the first factor of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='25) is negligible with  respect to that of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='24).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Similarly, since M = dim ρ, the second factor of  30  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='25) is smaller that that of (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='24) relative to our chosen ρ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In general the  new bound is much better.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' However, our argument applies only to fields F,  and representations ρ, of bounded degrees d, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  A more pertinent comparison, however, is with Zaman’s paper [21], which  gives an estimate for β (the smallest norm of a prime p of F that does not  split in E;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Zaman also assumes that p is of degree 1 over F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' ) For simplicity  we only consider the case where F = Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In this case [21, Cor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2], with  g = [E : Q], Zaman’s estimate is  β ≪ D  1+ε  4A(g−1)  E  ≪ (  �  ρ  (Nfρ)dim ρ)  1+ε  4A(g−1)  with A ≈ 1, to be compared with (this paper)  β ≪ N(fρ0)M/2+ε, M = dim ρ0  where ρ0 is our chosen representation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The comparison therefore depends  on the complexity of the Galois group G, in particular its number of large  representations and their ramification.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For larger fields F [21, Theorem1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1],  this is multiplied by a term at least of order exp(Ag(log DF)2) (here A is again  an implicit constant) and the product will likely be larger that the estimate  of Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Note also that Zaman does not assume the extensions to be  Galois.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Example: Assume ρ is associated to a normalised newform f of weight  1 on Γ0(q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then fρ = (q) ⊂ Z, and Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2 yields β ≪ q1+ε.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  4  Complements to [2] and remarks on a pa-  per of Friedlander–Iwanieˇc  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1  The method of Friedlander–Iwanieˇc, and the proof in the Appendix of [2],  use only the L–function of a (putative) representation π.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular, they  apply to the Rankin L–function L(s, π1 ⊠π2) of two cuspidal representations  31  of GL(m1, A) and GL(m2, A).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' In particular, we have:  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='1)  The lower bounds on the quadratic integrals  of L(s) in Theorems A − D of [2]are true  if L(s) = L(s, π1 ⊠ π2), π1, π2 cuspidal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Assume moreover π1, π2 tempered, and π1,∞, π2,∞ self–dual.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Let  L(s, π1 ⊠ π2) = � ann−s and  A(x) = �  n≤x  ann−s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Then  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2)  A(x) = κx + O(D  1  m+1x1−  2  m+1+ε)  where m = m1m2, and κ is the usual residue, and D is the conductor of  L(s, π1 × π2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The estimation of As(x) in [2, Thm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2], also applies;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' for π1 ≇ ˜π2| |ia,  this yields:  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3)  The abscissa of convergence of L(s, π1 ⊠ π2)  satisfies σc ≤ 1 −  2  m+1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='2  However, the results of Chapter 2 on “short” integrals do not apply in general  to Rankin L–functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Indeed Molteni uses the properties of L(s, π ⊠ ˜π);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  for π = π1 ⊠ π2, this would assume the properties of the L–function of a  quadruple tensor product.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='3  In [2, §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4] we discussed the relation between the exponent ν of an estimate  of A0(x):  A0(x) = O(xν+ε)  where A0(x) is associated to a cuspidal π, and the convexity estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' For  simplicity we assume L(s, π) holomorphic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We have the relation  � ∞  1  A0(x)x−sdx  x = L(s)  s  32  (Re(s) > ν).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Suppose s = σ + it, σ > ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' This can be written as  � ∞  0  A0(eX)e−σXe−itXdX.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The function A0(eX)e−σX is exponentially decreasing, and therefore this  Fourier transform is a C0 function of t;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' this implies that µ(σ) ≤ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The convexity estimate for µ(σ) is m  2 (1 − σ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Thus µ(σ) ≤ 1 beats the  convexity estimate if σ < 1 − 2  m.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Friedlander and Iwaniec have shown that the exponent ν = 1− 2  m could be  obtained for L(s) = L(s, π1)L(s, π2) and m = m1 + m2, m1, m2 ≥ 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' See [4,  §3]2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' We see that any improvement on ν = 1− 2  m would lead to subconvexity  (in the t–aspect) quite generally for GL(m) (and not only over Q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=') 3 If we  assume the optimum value conjectured by them, ν = 1  2 −  1  2m, we obtain the  following approximation of the Lindel¨of Conjecture:  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='4)  µ(σ) ≤ m  2 − m(m − 2)  m − 1  σ  (σ ≤ 1  2 − 1  2m)  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='5)  µ(σ) ≤  2m  m + 1(1 − σ)  (σ ≥ 1  2 − 1  2m).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  The restriction to two factors is not one when subconvexity is concerned,  because the estimate for L(s, π × π) implies one for L(s, π).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  References  [1] Calegari, Frank The Artin conjecture for some S5-extensions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Ann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  356 (2013), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 1, 191-207.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [2] Clozel, Laurent A universal lower bound for certain integrals of automor-  phic L-functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' With an appendix by L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Clozel and Peter Sarnak.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' arxiv:  2203.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='12475.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [3] Erd´elyi, Arthur;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Magnus, Wilhelm;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Oberhettinger, Fritz;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Tricomi,  Francesco G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Higher transcendental functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Vol II.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Based, in part, on  notes left by Harry Bateman.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' McGraw-Hill Book Co.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', New York-  Toronto-London, 1953.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  2They do not, however, give the proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' It has been explained to the author by Fried-  lander and Brumley.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  3For GL(n) over Q this has been recently proved by Nelson [15]  33  [4] Friedlander, John B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Iwaniec, Henryk Summation formulae for coeffi-  cients of L-functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Canad.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 57 (2005), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 3, 494-505.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [5] Harcos, Gergely Uniform approximate functional equation for principal  L-functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Res.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 2002, no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 18, 923-932.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [6] Harcos, Gergely Erratum to: ”Uniform approximate functional equation  for principal L-functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' ” Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Res.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 2004, no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 13, 659-660.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [7] Iwaniec, Henryk;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Kowalski, Emmanuel Analytic number theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Ameri-  can Mathematical Society Colloquium Publications, 53.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' American Math-  ematical Society, Providence, RI, 2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [8] Jacquet,  H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Piatetski-Shapiro,  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Shalika,  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Conducteur des  repr´esentations du groupe lin´eaire.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Ann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 256 (1981), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 2, 199-  214.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [9] Kadiri, Habiba;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Ng, Nathan;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Wong, Peng-Jie The least prime ideal in the  Chebotarev density theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Amer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 147 (2019), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 6,  2289-2303.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [10] Lagarias, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Odlyzko, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Effective versions of the Chebotarev den-  sity theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Algebraic number fields: L-functions and Galois properties  (Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Sympos.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', Univ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Durham, Durham, 1975), pp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 409-464.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Academic  Press, London, 1977.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [11] Lagarias, J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Montgomery, H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=';' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Odlyzko, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' A bound for the  least prime ideal in the Chebotarev density theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Invent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 54  (1979), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 3, 271-296.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [12] Li, Xiannan Upper bounds on L-functions at the edge of the critical  strip.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Res.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' IMRN 2010, no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 4, 727-755.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [13] Luo, Wenzhi;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Rudnick, Ze´ev;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Sarnak, Peter On the generalized Ramanu-  jan conjecture for GL(n).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Automorphic forms, automorphic representa-  tions, and arithmetic (Fort Worth, TX, 1996), 301-310, Proc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Sympos.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Pure Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', 66, Part 2, Amer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', Providence, RI, 1999.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [14] Molteni, Giuseppe Upper and lower bounds at s=1 for certain Dirichlet  series with Euler product.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Duke Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 111 (2002), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 1, 133-158.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  34  [15] Nelson, Paul D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', Bounds for standard L-functions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' arxiv: 2109.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='15230.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [16] Neukirch, J¨urgen Algebraische Zahlentheorie.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Springer-Verlag, Berlin,  1992.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' [English: Neukirch, J¨urgen Algebraic number theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Translated  from the 1992 German original and with a note by Norbert Schappacher.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  With a foreword by G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Harder.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Grundlehren der mathematischen Wis-  senschaften, 322.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Springer-Verlag, Berlin, 1999.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=']  [17] Petrow, Ian;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Young, Matthew P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' The Weyl bound for Dirichlet L-  functions of cube-free conductor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Ann.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' of Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' (2) 192 (2020), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 2,  437-486.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [18] Ramachandra, K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Fractional moments of the Riemann zeta-function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Acta Arith.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 78 (1997), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 3, 255-265.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [19] Titchmarsh, E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Introduction to the theory of Fourier integrals.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Third  edition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Chelsea Publishing Co.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=', New York, 1986.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [20] Zaman, Asif Bounding the least prime ideal in the Chebotarev density  theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Funct.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Approx.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Comment.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 57 (2017), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 1, 115-142.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  [21] Zaman, Asif The least unramified prime which does not split completely.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Forum Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 30 (2018), no.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content=' 3, 651-661.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
+page_content='  Laurent Clozel  Math´ematiques, Bˆatiment 307  Universit´e Paris-Saclay  91405 Orsay Cedex  France  35' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/wtAzT4oBgHgl3EQfQfse/content/2301.01198v1.pdf'}
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+arXiv:2301.13227v1  [math.AG]  30 Jan 2023
+COINVARIANTS OF VERTEX ALGEBRAS
+ON MODULI OF ABELIAN VARIETIES
+NICOLA TARASCA
+Abstract. For a vertex operator algebra with Heisenberg symmetries,
+we construct spaces of coinvariants at principally polarized abelian va-
+rieties with respect to the action of an infinite-dimensional Lie algebra.
+We show how these spaces globalize to twisted D-modules on moduli
+of principally polarized abelian varieties, and we determine the Atiyah
+algebra of a line bundle acting on them. We prove analogous results on
+the universal abelian variety.
+Introduction
+Spaces of coinvariants have classically been constructed by assigning rep-
+resentations of affine Lie algebras, and more generally, vertex operator al-
+gebras, to algebraic curves [TUY, FBZ]. These spaces globalize to quasi-
+coherent sheaves carrying a twisted D-module structure on moduli of curves.
+Said structure is induced by an equivariant action of the Virasoro algebra on
+vertex operator algebra modules and on moduli of curves with marked points
+and formal coordinates. The construction generalizes to produce twisted D-
+modules on moduli spaces parametrizing pointed curves with extra features:
+line bundles, principal bundles, and D-bundles [FS, FBZ, BZN].
+Removing curves out of the picture, Arbarello–De Concini [ADC] con-
+structed a moduli space �
+Ag of suitable extensions of principally polarized
+abelian varieties which includes, via an extended Torelli map, the moduli
+space �
+Mg of algebraic curves with a marked point and a formal coordinate.
+They showed that an infinite-dimensional symplectic algebra sp (H′) acts
+transitively on �
+Ag, extending the transitive action of the Witt algebra on
+�
+Mg. Here, H′ is the Lie subalgebra of the infinite-dimensional Heisenberg
+algebra consisting of elements with zero constant term. The oscillator rep-
+resentation which injects the Witt algebra into sp (H′) thus appears as the
+differential of the extended Torelli map.
+The present project started from the realization that the results of [ADC]
+offer an opening for an extension of the classical conformal field theory
+from moduli spaces of curves to moduli spaces of abelian varieties. Remov-
+ing curves out of the construction of coinvariants, we thus build and study
+twisted D-modules on moduli spaces of abelian varieties.
+Our construction proceeds as follows. For a vertex operator algebra V
+admitting an embedding of the rank one Heisenberg vertex algebra π → V ,
+MSC2020.
+14K10, 17B65, 17B66, 17B69, 14F06 (primary), 14K25, 14L15 (secondary).
+Key words and phrases. Infinite-dimensional Lie algebras, moduli of abelian varieties,
+symplectic and metaplectic algebras, connections and Atiyah algebras, vertex operator
+algebras, Heisenberg symmetries, sheaves of coinvariants, conformal field theory.
+1
+
+2
+N. TARASCA
+we define the space of coinvariants of V at a point a ∈ �
+Ag as
+(0.1)
+�V(V )a := V / spF
+�
+H′�
+· V,
+where spF (H′) is the stabilizer of sp (H′) at a—see (2.7). The space (0.1)
+is the largest quotient of V on which spF (H′) acts trivially. We show that
+the spaces (0.1) globalize to a sheaf �V(V ) on �
+Ag. Furthermore, in case V is
+Heisenberg–admissible, as per Definition 6.1, we show that the sheaf �V(V )
+descends on the moduli space Ag of principally polarized, g-dimensional
+abelian varieties:
+Theorem 1. For a Heisenberg–admissible vertex algebra V , the spaces of
+coinvariants (0.1) give rise to a twisted D-module V(V ) on Ag.
+For instance, the theorem applies to Heisenberg vertex algebras of ar-
+bitrary rank and even lattice vertex algebras.
+The metaplectic algebra
+mp (H′)—reviewed in §1.4—acts on �
+Ag via the projection mp (H′) → sp (H′)
+and on V thanks to the embedding π → V and replaces the Virasoro algebra
+of the classical conformal field theory. These actions induce the twisted D-
+module structure on V(V ). To explicitly determine it, we use the formalism
+of Atiyah algebras from Beilinson-Schechtman [BS]. Let Λ be the Hodge line
+bundle on Ag, and FΛ the Atiyah algebra of Λ, i.e., the sheaf of first-order
+differential operators acting on Λ.
+We say that a Heisenberg–admissible
+vertex algebra V is of central charge c if the embedding π → V induces an
+action of the Virasoro algebra on V of central charge c—see §6.
+Theorem 2. For a Heisenberg–admissible vertex algebra V of central charge
+c, the sheaf V(V ) on Ag carries an action of the Atiyah algebra c
+2 FΛ. This
+action induces the twisted D-module structure on V(V ).
+Moreover, we extend these results over the universal abelian variety. It is
+shown in [ADC] that �
+Ag admits a universal family �
+Xg → �
+Ag. This extends
+the universal family Xg over the stack Ag. The space �
+Xg carries a transitive
+action of the Lie algebra sp (H′) ⋉ H′. We define the space of coinvariants
+of V at x ∈ �
+Xg as
+(0.2)
+�V(V )x := V /
+�
+spF
+�
+H′�
+⋉ F
+�
+· V,
+where spF (H′) ⋉ F is the stabilizer of sp (H′) ⋉ H′ at x.
+Theorem 3. For a Heisenberg–admissible vertex algebra V , the spaces of
+coinvariants (0.2) give rise to a twisted D-module V(V ) on Xg.
+The twisted D-module structure is explicitly determined by the action of
+an appropriate multiple of the Atiyah algebra FΘ of the theta line bundle
+Θ on Xg:
+Theorem 4. For a Heisenberg–admissible vertex algebra V of central charge
+c, the sheaf V(V ) on Xg carries an action of the Atiyah algebra −c FΘ. This
+action induces the twisted D-module structure on V(V ).
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES
+3
+To prove the above statements, we need to show some auxiliary results,
+which are of independent interest. It is shown in [ADCKP] that for g ≥ 3,
+there are canonical isomorphisms
+H2 (Witt, C) ∼= H2 (Mg, C) ,
+H2 �
+Witt ⋉ H′, C
+� ∼= H2 �
+P′
+d, C
+�
+,
+where Mg is the moduli space of smooth genus g curves, and P′
+d is the moduli
+space of quadruples (C, P, v, L ), where C is a smooth genus g curve, P is
+a point of C, v is a nonzero tangent vector to C at P, and L is a degree d
+line bundle on C. We show that these isomorphisms extend to give:
+Theorem 5. For g ≥ 3, one has canonical isomorphisms
+H2 �
+sp
+�
+H′�
+, C
+� ∼= H2 (Ag, C) ,
+H2 �
+sp
+�
+H′�
+⋉ H′, C
+� ∼= H2 (Xg, C) .
+Moreover, we study group (ind)-schemes of symplectic automorphisms
+in §3, generalizing the group (ind)-schemes of ring automorphisms from
+[BD, FBZ]. Our constructions of the sheaves of coinvariants on Ag and Xg
+are thus variations on the formalism of localization of modules over Harish-
+Chandra pairs (§9.1). The present results are intended to initiate the study
+of coinvariants on abelian varieties and their moduli.
+We mention some
+natural directions in §9 and will return to these in the near future.
+The paper is structured as follows. We review the algebraic and geometric
+background in §§1 and 2, respectively. In §3 we define and study a group
+scheme which acts transitively on the fibers of the natural map �
+Ag → Ag,
+together with related group (ind-)schemes. In §4 we start the study of the
+cohomology of the Lie algebras sp (H′) and sp (H′) ⋉ H′. In §5 we prove
+Theorem 5.1, which establishes two canonical isomorphisms of H2 spaces.
+Theorem 5 follows from Theorem 5.1 and Proposition 2.4. In Corollary 5.2
+we describe the Atiyah algebras of the Hodge and theta line bundles. Next,
+an intermezzo in §6 contains a review of vertex algebras and their required
+properties. We construct sheaves of coinvariants on �
+Ag and �
+Xg in §7 and
+descend them on Ag and Xg in §8, where we prove Theorems 1–4.
+We
+conclude with some final remarks in §9. Throughout, we work over C.
+1. Heisenberg, metaplectic, and Virasoro algebras
+We review here the infinite-dimensional Lie algebras from [ADCK, ADC]
+which will play a role in the paper. The complex Lie algebras from these
+references are here promoted to functors on commutative C-algebras, as
+needed for our geometric constructions. Moreover, emphasis is given to the
+two-cocycles defining the relevant central extensions, later needed in §§4–5.
+Here is some notation used throughout. For a topological vector space V ,
+a subset B ⊂ V is said to topologically generate V if finite linear combina-
+tions of elements of B form a dense open subspace of V . Also, let gl(V ) be
+the Lie algebra of continuous linear endomorphisms of V .
+
+4
+N. TARASCA
+1.1. The algebra of formal Laurent series. Let H be the functor which
+assigns to a C-algebra R the R-algebra H(R) := R((t)) of formal Laurent
+series in a parameter t. One has a decomposition
+H = H+ ⊕ H−,
+where
+H+(R) := R�t�
+and
+H−(R) := t−1R[t−1].
+Also, let H′ be the functor which assigns to R the R-module H′(R) ⊂ H(R)
+of Laurent series with zero constant term:
+H′ := H′
++ ⊕ H−
+where H′
++ := t H+.
+The R-module H(R) is endowed with the t-adic topology. This is the
+topology that has the collection of cosets
+�
+f + tNH+ | f ∈ H and N ≥ 1
+�
+as a basis of open subsets. This gives H the structure of a complete topo-
+logical space, topologically generated over R by bi := ti for i ∈ Z.
+We will repeatedly use the following result from [ADCK]: the Lie algebra
+gl(H) has a canonical two-cocycle given by
+(1.1)
+ψ (A, B) := Tr (π+ A π− B π+ − π+ B π− A π+)
+for A, B ∈ gl(H),
+where π+ : H → H+ and π− : H → H− are the natural projections.
+1.2. The Heisenberg algebra. Consider the symplectic form ⟨ , ⟩ on H
+given by
+(1.2)
+⟨f, g⟩ := − Res
+t=0 f dg
+for f, g ∈ H.
+This only depends on df and dg, for f, g ∈ H, and restricts to a nondegener-
+ate symplectic form on H′. The Heisenberg algebra is the Lie algebra struc-
+ture on H given by the Lie bracket ⟨ , ⟩. As (1.2) is continuous with respect
+to the t-adic topology, the Heisenberg algebra H is a complete topological
+Lie algebra.
+Moreover, (1.2) is invariant by changes of the parameter t.
+Note that ⟨f, g⟩ = ψ(f, g), where ψ is from (1.1), and f, g ∈ H act on H by
+multiplication. Thus, the Heisenberg algebra H is the central extension
+0 → gl1 1 → H → H′ → 0
+given be the restriction of the two-cocycle ψ, where 1 := b0, and gl1 is the
+functor assigning to a C-algebra R the trivial Lie algebra R.
+1.3. The enveloping algebra U (H). Let U (H) be the quotient of the
+universal enveloping algebra of the Heisenberg algebra H by the two-sided
+ideal generated by 1 − 1, where 1 is the central element of H, and 1 is the
+unit in the universal enveloping algebra. The algebra U (H) has a canonical
+filtration U0(H) ⊂ U1(H) ⊂ · · · , where U0(H) = gl1 1, and UN(H) for
+N ∈ N assigns to a C-algebra R the R-module generated by the products
+f1 · · · fm with m ≤ N and fi ∈ H for i ≤ N.
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES
+5
+Remarkably, U2(H) is a Lie subalgebra of U (H) for the Lie bracket given
+by the commutator. Explicitly, the Lie bracket in U2(H) is given by
+[f, g] = ⟨f, g⟩,
+[f, 1] = [fg, 1] = 0,
+[fg, k] = ⟨f, k⟩ g + ⟨g, k⟩ f,
+[fg, kl] = ⟨g, k⟩ fl + ⟨f, k⟩ gl + ⟨g, l⟩ kf + ⟨f, l⟩ kg
+(1.3)
+for f, g, k, l ∈ H′. One has
+U2(H)/gl1 1 ∼= S2(H′) ⋉ H′
+as Lie algebras, where S2(H′) is the second symmetric power of H′, and the
+semidirect product is given by the action of S2(H′) on H′ induced by
+(1.4)
+fg: H′ → H′,
+k �→ ⟨f, k⟩ g + ⟨g, k⟩ f,
+for f, g, k ∈ H′.
+Hence, U2(H) is a central extension
+0 → gl1 1 → U2(H) → S2(H′) ⋉ H′ → 0.
+To identify the corresponding two-cocycle, arguing by cases, one shows that
+[: fg :, : kl :]
+=
+−1
+2 ψ (fg, kl) 1
++⟨g, k⟩ : fl : +⟨f, k⟩ : gl : +⟨g, l⟩ : kf : +⟨f, l⟩ : kg :
+in U2(H) is compatible with (1.3), where : : denotes the normal order prod-
+uct giving a specific lift of elements from S2(H′) to U2(H), and ψ is the
+restriction of the two-cocycle in (1.1).
+Hence, the two-cocycle c defining
+U2(H) is given by
+c(fg, kl) = −1
+2 ψ (fg, kl) ,
+c(f, g) = ⟨f, g⟩,
+c(fg, k) = 0
+for f, g, k, l ∈ H′.
+We will need a completion of U2(H).
+For this, we first introduce the
+completion of S2(H′) given by the symplectic algebra and its corresponding
+extension.
+1.4. Symplectic and metaplectic algebras. The symplectic algebra sp (H′)
+is the Lie subalgebra of gl(H′) defined as
+sp
+�
+H′�
+:=
+�
+X ∈ gl(H′) | ⟨Xa, b⟩ + ⟨a, Xb⟩ = 0, for all a, b ∈ H′�
+.
+The action of S2(H′) on H′ induced by (1.4) realizes S2(H′) as a dense Lie
+subalgebra of sp (H′).
+The metaplectic algebra mp (H′) is the central extension
+(1.5)
+0 → gl1 1 → mp
+�
+H′�
+→ sp
+�
+H′�
+→ 0
+defined by the two-cocycle
+(1.6)
+− 1
+2 ψ (X, Y )
+for X, Y ∈ sp (H′)
+where ψ is the restriction of (1.1).
+
+6
+N. TARASCA
+1.5. The Weyl algebra. The Weyl algebra
+�
+U (H) is the completion of
+the algebra U (H) with respect to the topology in which the basis of open
+neighborhoods of 0 is formed by the left ideals of the submodules
+tNH+ ⊂ H ⊂ �
+U (H)
+for N ∈ Z
+[FBZ, §2.1.2]. Elements of �
+U (H) can be described as possibly infinite series
+of the form A0 + �
+i≥1 Ai bi with Ai equal to a finite linear combination of
+finite formal products of elements in {bj}j∈Z for i ≥ 0.
+The closure �
+U2(H) of U2(H) in �
+U (H) is a complete topological Lie sub-
+algebra of �
+U (H) for the Lie bracket given by the commutator. Explicitly,
+consider first the semidirect product sp (H′) ⋉ H′ given by the action
+[X, f] = X(f)
+for X ∈ sp (H′) and f ∈ H′.
+Hence, the Lie bracket for sp (H′) ⋉ H′ is
+[X + f, Y + g] = XY − Y X + X(g) − Y (f)
+for X, Y ∈ sp (H′) and f, g ∈ H′. Then, one has a central extension
+(1.7)
+0 → gl1 1 → �
+U2(H) → sp
+�
+H′�
+⋉ H′ → 0
+with two-cocycle c given by
+c(X, Y ) = −1
+2 ψ (X, Y ) ,
+c(f, g) = ⟨f, g⟩,
+c(X, f) = 0
+(1.8)
+for X, Y ∈ sp (H′) and f, g ∈ H′, where ψ is the restriction of (1.1). This is
+compatible with the Lie bracket for U2(H) in (1.3).
+The metaplectic algebra mp (H′) is realized as a Lie subalgebra of �
+U2(H)
+via the injection
+(1.9)
+mp
+�
+H′�
+֒→ �
+U2(H),
+1 �→ 1,
+X �→ X
+for X ∈ sp (H′).
+1.6. Witt and Virasoro algebras. The Witt algebra Witt is the functor
+assigning to a C-algebra R the Lie algebra R((t))∂t of continuous deriva-
+tions of R((t)). It is topologically generated over R by Lp := −tp+1∂t for
+p ∈ Z, with relations [Lp, Lq] = (p − q)Lp+q for p, q ∈ Z. The oscillator
+representation of Witt gives an injection of Lie algebras
+(1.10)
+τ : Witt ֒→ sp
+�
+H′�
+,
+Lp �→ 1
+2
+�
+i
+b−i bi+p
+where the sum is over i ∈ Z \ {0, −p}.
+The Virasoro algebra Vir is the central extension
+0 → gl1 1 → Vir → Witt → 0
+with Lie bracket given by
+[Lp, Lq] = (p − q) Lp+q + 1
+12 (p3 − p) δp+q,0 1,
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES
+7
+mp (H′)
+�
+U2(H)
+Vir
+D
+sp (H′)
+sp (H′) ⋉ H′
+Witt
+Witt ⋉ H′.
+�τ
+�σ
+τ
+σ
+Figure 1. The main Lie algebra maps.
+where δp+q,0 = 1 when p + q = 0, and δp+q,0 = 0 otherwise. The two-cocycle
+defining this extension is the restriction over Witt of the two-cocycle (1.6).
+The map τ is lifted by the injection
+(1.11)
+�τ : Vir ֒→ mp
+�
+H′�
+,
+Lp �→ 1
+2
+�
+i
+: b−i bi+p :,
+1 �→ 1
+where the sum is over i ∈ Z \ {0, −p}.
+1.7. The map σ and the Lie algebra D. We will need the Lie algebra
+injection
+(1.12)
+σ: Witt ⋉ H′ ֒→ sp
+�
+H′�
+⋉ H′,
+Lp �→ 1
+2
+�
+i
+b−i bi+p − p + 1
+2
+bp,
+bq �→ bq
+where the sum is over i ∈ Z \ {0, −p}.
+For p = 0, one simply has
+L0 �→ 1
+2
+�
+i b−i bi, since b0 vanishes in H′.
+Remark 1.1. There are infinitely many ways of injecting Witt ⋉ H′ in
+sp (H′) ⋉ H′: by replacing in (1.12) the coefficient − p+1
+2
+with a(p + 1)
+for a ∈ C, one obtains a one-parameter family of such injections, as in the
+Segal-Sugawara construction [FBZ, 5.2.8]. The case a = − 1
+2 is specifically
+needed in §2.6.
+Finally, let D be the central extension
+0 → gl1 1 → D → Witt ⋉ H′ → 0
+defined by the restriction to Witt ⋉ H′ of the two-cocycle ψ from (1.1) such
+that Witt acts on H as in (1.10) and H′ acts on H by multiplication. The
+map σ is lifted by the injection
+(1.13)
+�σ: D ֒→ �
+U2(H),
+Lp �→ 1
+2
+�
+i
+: b−i bi+p : − p + 1
+2
+bp,
+bq �→ bq,
+1 �→ 1
+where the sum is over i ∈ Z \ {0, −p}.
+
+8
+N. TARASCA
+The main Lie algebra maps of this section are summarized by the com-
+mutative diagram in Figure 1. There, the four horizontal surjections admit
+Lie algebra splittings, and the left and right squares are Cartesian.
+2. Extended abelian varieties and their moduli
+First, we review some geometric constructions and results from [ADC] re-
+lated to suitable extensions of abelian varieties and their moduli. Theorems
+2.2 and 2.3 play a key role in later sections. Then, we conclude with a review
+of the degree-2 cohomology classes on the moduli spaces in consideration.
+2.1. Extended abelian varieties. Recall the symplectic form ⟨ , ⟩ on H′
+from (1.2).
+An extended principally polarized abelian variety (extended
+PPAV, for short) of dimension g is a triple (Z, F, L), where
+Z is a Lagrangian subspace of H′,
+F is a codimension g subspace of Z, and
+L is a rank 2g lattice in F ⊥/F,
+satisfying four suitable conditions. The form ⟨ , ⟩ on H′ induces a nonde-
+generate symplectic form on F ⊥/F, which will still be denoted as ⟨ , ⟩. The
+first three conditions imposed on the triple (Z, F, L) are:
+Z ∩ H′
++ = 0,
+(2.1)
+LR ∩ A = 0
+where
+LR := L ⊗Z R
+and
+A := F ⊥ ∩ H′
++,
+(2.2)
+1
+2πi ⟨ , ⟩ is unimodular on L.
+(2.3)
+Condition (2.1) implies the decompositions
+H′ = Z ⊕ H′
++
+and
+F ⊥/F = Z/F ⊕ A
+into maximal isotropic subspaces. It follows that F ⊥/F has dimension 2g.
+Condition (2.2) implies that: the projection F ⊥/F → Z/F induces a real
+isomorphism LR ∼= Z/F; the real structure on F ⊥/F induced by LR identi-
+fies A with the conjugate of Z/F; and the form on Z/F given by
+B(u, v) := 1
+π ⟨u, v⟩
+for u, v ∈ Z/F
+is Hermitian. The fourth and last condition on the triple (Z, F, L) is
+(2.4)
+the form B on Z/F is positive definite.
+A triple (Z, F, L) satisfying the four conditions (2.1)-(2.4) determines an
+abelian variety X, which is the quotient of the g-dimensional space Z/F by
+the image of L under the projection F ⊥/F → Z/F, equipped with the po-
+larization B, which is principal by (2.3). More precisely, the triple (Z, F, L)
+is equivalent to an isomorphism class of extensions
+(2.5)
+0 → H′
++ → H′/K → X → 0
+where K is the preimage of L under the projection F ⊥ → F ⊥/F.
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES
+9
+2.2. Moduli of extended PPAVs. In [ADC], the set
+�
+Ag of extended
+PPAVs of dimension g is endowed with the structure of an infinite-
+dimensional analytic manifold. We sketch here the construction. Consider
+the infinite-dimensional analytic manifold
+�
+Hg := �S2(H′
++) × Bg(H′
++) × Hg
+where
+�S2 �
+H′
++
+�
+:=
+�
+ϕ: H− → H′
++
+�����
+ϕ is linear and symmetric,
+i.e., ⟨a, ϕ(b)⟩ = ⟨ϕ(a), b⟩ for all a, b ∈ H−
+�
+,
+Bg(H′
++) := the manifold of frames of (H′
++)g,
+Hg := the Siegel upper half-space of degree g.
+The symplectic group Sp(2g, Z) acts freely and properly discontinuously on
+�
+Hg, hence the quotient �
+Hg / Sp(2g, Z) has a natural structure of an infinite-
+dimensional analytic manifold. Moreover, one has a bijection of sets
+(2.6)
+�
+Hg / Sp(2g, Z) → �
+Ag.
+Hence, (2.6) induces on �
+Ag the structure of an infinite-dimensional analytic
+manifold [ADC, §3]. One has a commutative diagram
+�
+Hg
+�
+Ag
+Hg
+Ag
+/ Sp(2g,Z)
+/ Sp(2g,Z)
+where Ag is the moduli space of principally polarized abelian varieties of
+dimension g. The action of Sp(2g, Z) on Hg has finite nontrivial stabilizers,
+hence at least an orbifold structure is required on Ag. Here we consider Ag as
+the resulting quotient stack. This is a separated, smooth Deligne-Mumford
+stack. From [ADC], �
+Ag is rational homotopy equivalent to Ag.
+Remark 2.1. To treat
+�
+Ag and Ag on an equal footing, we will consider
+families (Z, F, L) → S of extended PPAVs of dimension g over a smooth
+scheme S. We will construct sheaves of coinvariants on such families in §7
+and descend them to families of PPAVs in §8, thus yielding sheaves on Ag.
+2.3. Symplectic uniformization of moduli of extended PPAVs. An
+action of a Lie algebra g on a variety X over C is a homomorphism of Lie
+algebras g → Vect(X), where Vect(X) is the Lie algebra of regular vector
+fields on X.
+The action is said to be transitive if for every x ∈ X, the
+evaluation map g → Tx(X) is surjective.
+Theorem 2.2 (Uniformization of �
+Ag [ADC]). The moduli space �
+Ag carries
+a transitive action of sp (H′). For (Z, F, L) in �
+Ag, one has
+T(Z,F,L)
+�
+�
+Ag
+�
+∼= spF
+�
+H′�
+\ sp
+�
+H′�
+
+10
+N. TARASCA
+where
+(2.7)
+spF
+�
+H′�
+:=
+�
+X ∈ sp
+�
+H′�
+| X
+�
+F ⊥�
+⊆ F
+�
+.
+We sketch the proof from [ADC]: using the map (2.6), and since the
+action of Sp(2g, Z) on �
+Hg is properly discontinuous, one deduces
+T(Z,F,L)
+�
+�
+Ag
+�
+∼= �S2 �
+H′
++
+�
+×
+�
+H′
++ ⊗ Z/F
+�
+× S2 (Z/F) .
+This is then shown to be isomorphic to spF (H′) \ sp (H′). We emphasize
+that the subspace
+(2.8)
+�S2(H′
++) ×
+�
+H′
++ ⊗ Z/F
+�
+is the tangent space to the fiber of the forgetful map �
+Ag → Ag at (Z, F, L).
+2.4. The universal extended PPAV. The moduli space �
+Ag admits a
+universal family �
+Xg → �
+Ag. The fiber over a point (Z, F, L) in �
+Ag is
+�
+H′/K
+�
+×G Q
+where G is the group of points of order 2 in H′/K, and Q is the G-torsor
+of integral quadratic forms q on L satisfying
+q(a) + q(b) − q(a + b) ≡
+1
+2πi ⟨a, b⟩
+mod 2.
+The need for the twist by G becomes clear when one defines the maps in
+(2.9). Points of �
+Xg are denoted as (Z, F, L, h, q). The map �
+Xg → �
+Ag has
+no zero-section, however the fiber over (Z, F, L) in �
+Ag is non-canonically
+isomorphic to H′/K. From [ADC], �
+Xg is rational homotopy equivalent to
+the universal family Xg over the stack Ag. More generally, we will consider
+families (Z, F, L, h, q) → S over a smooth scheme S.
+2.5. Uniformization of the universal extended PPAV. Recall the Lie
+algebra sp (H′) ⋉ H′ from §1.5.
+Theorem 2.3 (Uniformization of �
+Xg [ADC]). The moduli space �
+Xg carries
+a transitive action of sp (H′) ⋉ H′. For (Z, F, L, h, q) in �
+Xg, one has
+T(Z,F,L,h,q)
+�
+�
+Xg
+�
+∼= spF
+�
+H′�
+⋉ F \ sp
+�
+H′�
+⋉ H′.
+2.6. The case of curves and line bundles. The moduli spaces �
+Ag and
+�
+Xg are naturally extensions of moduli spaces of curves and line bundles. To
+see this, let �
+Mg be the moduli space of triples (C, P, t), where C is a smooth
+genus g curve, P is a point of C, and t is a formal coordinate at P [ADCKP].
+From [ADC], there is an extended Torelli map �
+Mg → �
+Ag mapping (C, P, t)
+to a triple (Z, F, L) with identifications
+F ∼= H0 (C \ P, OC) ,
+Z/F ∼= H1 (C, OC) ,
+L ∼= H1 (C, Z) .
+The isotropicity of F with respect to (1.2) follows from the residue theorem.
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 11
+Moreover, let �Pd → �
+Mg be the relative Picard variety parametrizing
+isomorphism classes of quintuples (C, P, t, L , ϕ) where L is a line bundle of
+degree d on C and ϕ is a trivialization of the restriction of L to the formal
+disc around P. For d = g − 1, one has a commutative diagram
+(2.9)
+�Pg−1
+�
+Xg
+�
+Mg
+�
+Ag
+where (C, P, t, L , ϕ) in �Pg−1 is mapped to (Z, F, L, h, q) in �
+Xg such that q is
+arbitrary in Q, and h is the unique point of H′/K given by the isomorphism
+class of
+�
+L η−1, ϕ dt− 1
+2
+�
+, where η is the unique theta-characteristic on C
+identified by q via Riemann’s theorem [ADC, (3.23)]. By the construction
+of �
+Xg, this map is independent of the choice of q.
+Recall the commutative diagram
+(2.10)
+Witt ⋉ H′
+sp (H′) ⋉ H′
+Witt
+sp (H′)
+σ
+τ
+from Figure 1. It is shown in [ADC, (5.11)] that the Lie algebras in (2.10)
+act transitively on the corresponding moduli spaces in (2.9), and the maps
+in (2.10) induce the differentials of the corresponding maps in (2.9).
+2.7. The Hodge and theta line bundles. Here we review the degree-2
+cohomology classes on the moduli spaces in consideration. Let Λ → Ag be
+the Hodge line bundle defined by
+Λ := det
+�
+π∗
+�
+ωXg/Ag
+��
+where π: Xg → Ag is the natural projection and ωXg/Ag is the relative dual-
+izing sheaf. Let Θ → Xg be the relative theta line bundle whose restriction to
+the fibers of π induces the principal polarization on each fiber. For simplic-
+ity, we omit the notation for the pull-back when referring to the pull-back
+of Λ and Θ via the nature projections �
+Ag → Ag and �
+Xg → Xg. Let λ and θ
+be the first Chern classes of Λ and Θ, respectively.
+Proposition 2.4. For g ≥ 2, one has
+H2 �
+�
+Ag, Z
+�
+= H2 (Ag, Z) = Zλ,
+(2.11)
+H2 �
+�
+Xg, Z
+�
+= H2 (Xg, Z) = Zλ ⊕ Zθ.
+(2.12)
+Moreover, for g ≥ 3, the pull-back via the extended Torelli map induces an
+identification
+(2.13)
+H2( �
+Ag, Z) =
+−→ H2 �
+�
+Mg, Z
+�
+= H2 (Mg, Z)
+
+12
+N. TARASCA
+and an inclusion
+(2.14)
+H2 �
+�
+Xg, Z
+�
+⊂ H2 �
+�Pg−1, Z
+�
+= H2 �
+P′
+g−1, Z
+�
+.
+The statement combines various results from the literature.
+Proof. For g ≥ 2, one has H2(Ag, Z) = Zλ, and for g ≥ 3, the Torelli map
+induces an identification H2(Ag, Z) = H2(Mg, Z) (e.g., [VDG, 8.1] and [Hai,
+17.3–17.4]). The last identity fails for g = 2, since H2(M2, Z) is generated
+by λ but cyclic of order 10.
+Since Ag and �
+Ag have the same rational homotopy type [ADC, pg. 16–
+17], (2.11) follows. Similarly, Xg and �
+Xg have the same rational homotopy
+type [ADC, pg. 17], hence the first isomorphism in (2.12).
+The second
+identification in (2.12) follows from [FP].
+Next, consider the composition of forgetful maps
+(2.15)
+�
+Mg → M′
+g → Mg
+where M′
+g is the moduli space of triples (C, P, v), where C is a curve of
+genus g, P is a point of C, and v is a nonzero tangent vector to C at P.
+Since �
+Mg and M′
+g have the same rational homotopy type and
+H2(M′
+g, Z) = H2(Mg, Z) = Zλ
+[ADCKP, 5.8], the composition of the maps in (2.15) induces an identifica-
+tion H2( �
+Mg, Z) = Zλ. Using (2.11), we deduce (2.13). Note that the class
+of the cotangent line bundle at the marked point vanishes on M′
+g and �
+Mg.
+Finally,
+�Pg−1 and P′
+g−1 have the same rational homotopy type and
+H2(P′
+g−1, Z) is described in [ADCKP, 5.7]: it has dimension three, and
+λ and θ are linearly independent. The inclusion (2.14) follows, hence the
+statement.
+□
+3. Group (ind-)schemes of symplectic automorphisms
+Here we study how to exponentiate the symplectic algebra sp (H′) and
+related Lie algebras. We use group ind-schemes as in [FBZ, §A.1.4]. For
+a topological vector space E, let GL(E) be the group of continuous linear
+automorphisms of E. Also, for a topological group G, let G◦ be its connected
+component of the identity.
+3.1. The Lie algebra sp+ (H′). Let sp+ (H′) be the Lie subalgebra of
+sp (H′) which preserves the subspace H′
++, that is:
+sp+ �
+H′�
+:=
+�
+X ∈ sp
+�
+H′�
+| X(H′
++) ⊆ H′
++
+�
+.
+This has the following geometric incarnation.
+Recall from (2.8) that for
+(Z, F, L) in �
+Ag, the tangent space to the fiber of the forgetful map �
+Ag → Ag
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 13
+at (Z, F, L) is �S2 �
+H′
++
+�
+×
+�
+H′
++ ⊗ Z/F
+�
+. One has a natural quotient of Lie
+algebras
+(3.1)
+sp+ �
+H′�
+։ �S2 �
+H′
++
+�
+×
+�
+H′
++ ⊗ Z/F
+�
+.
+The transitive action of sp (H′) on �
+Ag from §2.3 extends the transitive ac-
+tion of sp+ (H′) along the fibers of the forgetful map �
+Ag → Ag. Hence, the
+symplectic uniformization of �
+Ag induces the following double coset realiza-
+tion of the tangent space of Ag. For (Z, F, L) ∈ �
+Ag, let (X, B) ∈ Ag be the
+image of (Z, F, L) via �
+Ag → Ag as in (2.5). One has
+(3.2)
+T(X,B) (Ag) ∼= spF
+�
+H′�
+\ sp
+�
+H′�
+/ sp+ �
+H′�
+.
+3.2. The group scheme Sp+ (H′). We will need to exponentiate the Lie
+algebra sp+ (H′). For this, consider the group scheme of continuous sym-
+plectic automorphisms of H′ preserving the subspace H′
++, and let Sp+ (H′)
+be its connected component of the identity, that is:
+Sp+ �
+H′�
+:=
+�
+ρ ∈ GL(H′)
+�����
+⟨ρ(a), ρ(b)⟩ = ⟨a, b⟩
+for all a, b ∈ H′,
+ρ
+�
+H′
++
+�
+⊆ H′
++
+�
+◦
+.
+The group scheme Sp+ (H′) represents the group functor which assigns
+to a C-algebra R the identity component Sp+ (H′(R)) of the group of
+continuous symplectic automorphisms of H′(R) preserving the subspace
+H′
++(R) = tR�t�.
+One easily checks that
+Lie(Sp+ �
+H′)
+�
+= sp+ �
+H′�
+.
+Also, since Sp+ (H′) is by definition connected, elements in Sp+ (H′) are
+products of exponentials of elements in sp+ (H′).
+The adjoint action of the group scheme Sp+ (H′) on sp+ (H′) induces a
+transitive action of Sp+ (H′) on the fibers of �
+Ag → Ag, and Theorem 2.2 as
+shown in [ADC] can be recasted as:
+Theorem 3.1 (after [ADC]). The moduli space �
+Ag carries a transitive ac-
+tion of sp (H′) compatible with the transitive action of Sp+ (H′) on the fibers
+of �
+Ag → Ag.
+Remark 3.2. As the group GL(H) is not connected [ADCKP, pg. 11], taking
+the identity component in the definition of Sp+ (H′) can not be omitted
+without modifying the outcome.
+3.3. The group ind-scheme Sp (H′). More generally, consider the group
+functor which assigns to a C-algebra R the connected group Sp (H′(R)) of
+continuous linear automorphisms of H′(R) of the following type
+Sp
+�
+H′(R)
+�
+:=
+�
+ρ ∈ GL(H′(R))
+�����
+⟨ρ(a), ρ(b)⟩ = ⟨a, b⟩
+for all a, b ∈ H′,
+ρ
+�
+H′
++(R)
+�
+⊆ H′
++(R) ⊕ H−(Rn)
+�
+◦
+
+14
+N. TARASCA
+where Rn ⊆ R is the C-subalgebra consisting of nilpotent elements. The
+presence of nilpotent elements entails that this functor can only be repre-
+sented by an ind-scheme, as schemes are insufficient (this is as in [FBZ,
+§6.2.3]).
+Let Sp (H′) be the group ind-scheme representing this functor.
+Naturally, Sp+ (H′) is a subgroup of Sp (H′). One checks that
+Lie
+�
+Sp
+�
+H′��
+= sp
+�
+H′�
+.
+3.4. Derivations and ring automorphisms. Here we remark how the Lie
+algebras and group (ind-)schemes of this section naturally extend analogous
+objects studied in [BD, FBZ] and related to the geometry of curves. Namely,
+let Der(O) be the functor assigning to a C-algebra R the Lie algebra
+Der (O(R)) = R�t�∂t.
+This is the Lie subalgebra of the Lie algebra Witt(R) from (1.6) topologically
+generated over R by Lp for p ≥ −1. The inclusion τ : Witt ֒→ sp (H′) from
+(1.10) maps Der (O) to sp+ (H′), so that one has a commutative diagram of
+Lie algebras
+(3.3)
+Witt
+sp (H′)
+Der (O)
+sp+ (H′) .
+τ
+From [ADCKP], the moduli space �
+Mg carries a transitive action of Witt.
+This action is compatible with a simply transitive action of Der (O) on the
+fibers of �
+Mg → Mg: the elements Lp with p ≥ 0 topologically generate the
+tangent directions to the changes of the formal coordinate at the marked
+point, and the element L−1 spans the tangent space to the curve at the
+marked point. Hence, for (C, P, t) in �
+Mg, one has
+(3.4)
+TC (Mg) ∼= Vect(C \ P) \ Witt / Der (O) .
+From [ADC], the moduli space �
+Ag carries a transitive action of sp (H′) and
+by factoring Witt and sp (H′) by appropriate Lie subalgebras, the inclusion
+τ induces the differential of the extended Torelli map �
+Ag → �
+Mg.
+We emphasize how the transitive action of sp+ (H′) on the fibers of
+�
+Ag → Ag is naturally the extension of the simply transitive action of Der (O)
+on the fibers of �
+Mg → Mg, and (3.2) extends (3.4).
+One has a similar picture for the related group (ind-)schemes. Namely,
+consider first the group scheme Aut (O) representing the functor which as-
+signs to a C-algebra R the group of continuous ring automorphisms of R�t�
+preserving the ideal tR�t�. Explicitly, this is:
+Aut (O(R)) :=
+�
+t �→ a1 t + a2 t2 + . . . | ai ∈ R and a1 is a unit
+�
+.
+Since the symplectic form (1.2) is invariant by changes of the parameter t
+and tR�t� = H′
++(R) as vector spaces, it follows that Aut (O) is a subgroup of
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 15
+Sp+ (H′). However, the Lie algebra of Aut (O) is smaller than Der (O): As
+remarked in [FBZ, §6.2.3], one has Lie (Aut (O)) = t Der (O), and in order
+to exponentiate Der (O), one needs to consider a group ind-scheme. For this,
+let Aut (O) be the group ind-scheme representing the functor which assigns
+to a C-algebra R the group of continuous ring automorphisms of R�t�:
+Aut (O(R)) :=
+�
+t �→ a0 + a1 t + a2 t2 + . . .
+�����
+ai ∈ R, a1 is a unit,
+and a0 is nilpotent
+�
+.
+Similarly, let Aut (K) be the group ind-scheme representing the functor
+which assigns to a C-algebra R the group of continuous ring automorphisms
+of R((t)):
+Aut (K(R)) :=
+
+
+t �→
+�
+i≥i0
+ai ti
+�����
+ai ∈ R, a1 is a unit,
+ai nilpotent for i ≤ 0
+
+
+ .
+One has
+Lie (Aut (O)) = Der (O)
+and
+Lie (Aut (K)) = Witt.
+We refer to [BD, FBZ] for more on Der (O), Aut (O) and Aut (K).
+Elements in Aut (O) and Aut (K) naturally induce elements in GL(H),
+and after composing with the projection H → H′, they induce symplectic
+elements in GL(H′). Hence, one has a commutative diagram of group (ind)-
+schemes
+Aut (K)
+Sp (H′)
+Aut (O)
+Sp+ (H′)
+such that the differentials of these maps restricted to the tangent spaces at
+the identities are given by (3.3).
+3.5. The group ind-scheme Mp (H′). We will also consider the group
+ind-scheme Mp (H′) given by the central extension
+1 → Gm → Mp
+�
+H′�
+→ Sp
+�
+H′�
+→ 1
+corresponding to the metaplectic algebra mp (H′) from (1.5).
+3.6. The group scheme Sp+ (H′) ⋉ O×
+1 . Finally, we describe the analo-
+gous Lie algebras and group (ind)-schemes for the moduli space �
+Xg. The
+transitive action of sp (H′) ⋉ H′ on �
+Xg from §2.5 extends a transitive action
+of sp+(H′) ⋉ H′
++ on the fibers of �
+Xg → Xg. Let O×
+1 be the group scheme
+of invertible Taylor series with constant term 1. This is a subgroup of the
+group scheme O× of invertible Taylor series from [FBZ, §20.3.4]. One has
+Lie (O×) = H+ and Lie
+�
+O×
+1
+�
+= H′
++.
+
+16
+N. TARASCA
+Theorem 3.3 (after [ADC]). The moduli space �
+Xg carries a transitive ac-
+tion of sp (H′) ⋉ H′ compatible with the transitive action of Sp+ (H′) ⋉ O×
+1
+on the fibers of �
+Xg → Xg.
+4. On the cohomology of the Lie algebras
+Here we study the cohomology of the Lie algebras sp (H′) and sp (H′)⋉H′.
+We will then show in Theorem 5.1 that their H2 spaces are canonically
+isomorphic to H2 (Ag, C) and H2 (Xg, C), respectively.
+For a topological Lie algebra g, let H∗(g, C) be its continuous Lie algebra
+cohomology with complex coefficients.
+Recall the two-cocycle ψ of gl(H) from (1.1), and consider the two-
+cocycles on sp (H′) ⋉ H′
+α (X + f, Y + g) := ψ(X, Y ),
+β (X + f, Y + g) := ψ(f, g) = −Rest=0 f dg,
+γ (X + f, Y + g) := ψ(X, g) − ψ(Y, f)
+for X, Y ∈ sp (H′) and f, g ∈ H′, where f, g act on H by multiplication.
+Hence, ψ = α + β + γ on sp (H′) ⋉ H′. Restricting to Witt ⋉ H′, one has
+α (f∂t + g, h∂t + k) = 1
+6 Rest=0 f dh′′,
+γ (f∂t + g, h∂t + k) = −1
+2 Rest=0
+�
+f dk′ − h dg′�
+.
+Similarly, consider the two-cocycle α(X, Y ) := ψ(X, Y ) on sp (H′). It is
+shown in [ADCKP, 2.1] that H1 (Witt, C) = H1 (Witt ⋉ H′, C) = 0, and
+H2 (Witt, C) = C α
+and
+H2 �
+Witt ⋉ H′, C
+�
+= C α ⊕ C β ⊕ C γ
+where α is the class of α, and similarly for β and γ. Recall τ : Witt ֒→ sp (H′)
+from (1.10) and σ: Witt ⋉ H′ ֒→ sp (H′) ⋉ H′ from (1.12).
+Proposition 4.1. One has
+H1 �
+sp
+�
+H′�
+, C
+�
+= 0,
+(4.1)
+H1 �
+sp
+�
+H′�
+⋉ H′, C
+�
+= 0,
+(4.2)
+H2 �
+sp
+�
+H′�
+, C
+�
+= C α,
+(4.3)
+H2 �
+sp
+�
+H′�
+⋉ H′, C
+�
+= C α ⊕ C β.
+(4.4)
+Moreover, the pull-back via τ induces the identification
+τ ∗ : H2 �
+sp
+�
+H′�
+, C
+� =
+−→ H2 (Witt, C) ,
+and the pull-back via σ induces the injection
+σ∗ : H2 �
+sp
+�
+H′�
+⋉ H′, C
+�
+֒→ H2 �
+Witt ⋉ H′, C
+�
+,
+α �→ α,
+β �→ 1
+2 α + ψ.
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 17
+Remark 4.2. The two-cocycle defining the central extension mp (H′) of
+sp (H′) in (1.6) is − 1
+2 α. Also, the two-cocycle defining the central extension
+�
+U2(H) of sp (H′) ⋉ H′ in (1.8) is − 1
+2 α + β.
+Proof. Let H′
+f be the functor which assigns to a C-algebra R the R-
+subalgebra H′
+f(R) := R[t, t−1] ⊂ H′(R). One checks that
+S2 �
+H′
+f
+�
+=
+�
+S2 �
+H′
+f
+�
+, S2 �
+H′
+f
+��
+and
+S2 �
+H′
+f
+�
+⋉ H′
+f =
+�
+S2 �
+H′
+f
+�
+⋉ H′
+f, S2 �
+H′
+f
+�
+⋉ H′
+f
+�
+.
+Since H′
+f is dense in H′ and S2 (H′) is dense in sp (H′), we deduce
+sp
+�
+H′�
+=
+�
+sp
+�
+H′�
+, sp
+�
+H′��
+and
+sp
+�
+H′�
+⋉ H′ =
+�
+sp
+�
+H′�
+⋉ H′, sp
+�
+H′�
+⋉ H′�
+hence (4.1) and (4.2) follow.
+Next we prove (4.4). Assume δ is an arbitrary two-cocycle on sp (H′)⋉H′.
+Recall the relations
+(4.5)
+[Lp, Lq] = (p − q) Lp+q,
+[Lp, bq] = −q bp+q,
+[bp, bq] = 0
+on sp (H′) ⋉ H′, where Lp = −tp+1∂t and bq = tq for p, q ∈ Z. Considering
+terms of type
+δ(Lp, [Lq, Lr]),
+δ(Lp, [Lq, br]),
+δ(Lp, [bq, br])
+and imposing the two-cocycle relation
+δ(x, [y, z]) + δ(y, [z, x]) + δ(z, [x, y]) = 0
+for all x, y, z ∈ sp (H′) ⋉ H′ and the relations (4.5), a direct computation as
+in the proof of [ADCKP, 2.1] shows that
+δ (X + f, Y + g) ≡ A α (X + f, Y + g) + B β (X + f, Y + g)
++ C γ (X + f, Y + g)
+modulo coboundaries, for some A, B, C ∈ C. Next, consider the two-cocycle
+relation for
+x = b1b1,
+y = b1b−2,
+and
+z = b−1.
+Observe that
+[b1b−2, b−1] = b−2,
+[b−1, b1b1] = −2b1,
+[b1b1, b1b−2] = 0.
+Since
+γ (b1b1, b−2) = 2
+and
+γ (b1b−2, b1) = 0,
+it follows that the only non-trivial contribution to the two-cocycle relation
+is C γ (b1b1, [b1b−2, b−1]) = 0, hence C = 0. A direct analysis shows that the
+two-cocycle relations do not impose any relations on A and B, hence (4.4).
+The identification in (4.3) follows similarly from the argument for (4.4).
+For the final part of the statement, recall the map �σ : D ֒→
+�
+U2(H)
+from (1.13).
+Since the two-cocycle on Witt ⋉ H′ defining D is ψ, and
+
+18
+N. TARASCA
+the two-cocycle on sp (H′) ⋉ H′ defining �
+U2(H) is − 1
+2 α + β, we deduce
+σ∗ �
+− 1
+2 α + β
+�
+= ψ. A similar argument involving the map �τ from (1.11)
+shows that σ∗(α) = τ ∗(α) = α, hence the statement.
+□
+For a topological Lie algebra g, the space H2(g, C) classifies Lie algebra
+continuous central extensions of g up to isomorphism. Thus as a consequence
+of the previous statement, we have:
+Proposition 4.3. Let Z be a Lagrangian subspace of H′ with Z ∩ H′
++ = 0.
+Every Lie algebra continuous central extension
+0 → gl1 → �
+sp (H′) → sp
+�
+H′�
+→ 0
+—e.g., mp (H′)—splits over spF (H′) for all F ⊂ Z. Similarly, every Lie
+algebra continuous central extension
+0 → gl1 →
+�
+sp (H′) ⋉ H′ → sp
+�
+H′�
+⋉ H′ → 0
+—e.g., �
+U2(H)—splits over spF (H′) ⋉ F for all F ⊂ Z.
+Proof. One needs to show that the restriction of H2 (sp (H′) , C) to spF (H′)
+(respectively, the restriction of H2 (sp (H′) ⋉ H′, C) to spF (H′) ⋉ F) van-
+ishes for all F ⊂ Z.
+From Proposition 4.1, it is enough to consider the
+class of the two-cocycle α (resp., the classes of the two-cocycles α and β).
+Also, after rescaling to − 1
+2α as in Remark 4.2, we can reduce to the case
+�
+sp (H′) = mp (H′).
+For Z = H− and F ⊂ Z, one has F ⊂ H− ⊂ F ⊥, thus for X ∈ spF (H′),
+one has
+Im (π+ X π−) = π+ X(H−) ⊂ π+ X(F ⊥) ⊆ π+ F = 0.
+It follows that for F ⊂ H−, one has α(X, Y ) = 0 for all X, Y in spF (H′).
+Next, consider an arbitrary Lagrangian subspace Z of H′ with Z ∩ H′
++ = 0
+and a subspace F ⊂ Z. From §3.2, the group scheme Sp+ (H′) acts transi-
+tively on the space of such pairs (Z, F), hence there exists ρ ∈ Sp+ (H′) such
+that (Z, F) = ρ(H−, F) for some F ⊂ H−. Let mpF (H′) be the restriction
+of mp (H′) over spF (H′) and mpF (H′) the restriction over spF (H′). The
+adjoint action of the group ind-scheme Mp (H′) on mp (H′) factors through
+Sp (H′), hence
+Ad ρ
+�
+spF
+�
+H′��
+= spF
+�
+H′�
+and
+Ad ρ
+�
+mpF
+�
+H′��
+= mpF
+�
+H′�
+.
+Since we have shown that mpF (H′) is a trivial extension, it follows that
+mpF (H′) is a trivial extension, hence α(X, Y ) = 0 for all X, Y in spF (H′).
+The case of α on sp (H′) ⋉ H′ follows from α on sp (H′), and the case of
+β follows immediately from F being isotropic with respect to (1.2).
+□
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 19
+5. The isomorphism of second cohomology spaces
+Consider a variety X over C carrying a transitive action of a Lie algebra
+g (as defined in §2.3). For x ∈ X, let gx := Ker(g → Tx(X)). It is shown
+in [ADCKP, 4.1] that if gx = [gx, gx] for all x ∈ X, then every Lie algebra
+continuous central extension
+0 → C → �g → g → 0
+which splits over gx for all x ∈ X yields a continuous extension
+0 → X × C → E → T(X) → 0.
+This defines a canonical map
+(5.1)
+H2(g, C)0 → Ext1 (TX, OX) = H1 �
+Ω1
+X
+�
+where H2(g, C)0 ⊂ H2(g, C) is the subspace obtained by intersecting the
+kernels of the restriction maps H2(g, C) → H2(gx, C) for all x ∈ X.
+Combining Theorems 2.2 and 2.3 with Proposition 4.3, the above result
+from [ADCKP] applies to give canonical maps
+ν : H2 �
+sp
+�
+H′�
+, C
+�
+→ H2 �
+�
+Ag, C
+�
+,
+µ: H2 �
+sp
+�
+H′�
+⋉ H′, C
+�
+→ H2 �
+�
+Xg, C
+�
+.
+We determine these maps explicitly in terms of the basis elements of the H2
+spaces given in Propositions 4.1 and 2.4:
+Theorem 5.1. For g ≥ 3, one has
+λ = −ν [α] ,
+(5.2)
+λ = −µ [α] ,
+θ = 1
+2 µ [α] − µ [β] .
+(5.3)
+In particular, the maps µ and ν give canonical isomorphisms
+H2 �
+sp
+�
+H′�
+, C
+� ∼= H2 �
+�
+Ag, C
+�
+,
+H2 �
+sp
+�
+H′�
+⋉ H′, C
+� ∼= H2 �
+�
+Xg, C
+�
+.
+Proof. One has a commutative diagram
+(5.4)
+H2 (sp (H′) , C)
+H2 �
+�
+Ag, C
+�
+H2 (Witt, C)
+H2 �
+�
+Mg, C
+�
+ν
+=
+τ ∗
+=
+ν
+where the map τ ∗ is the identification studied in Proposition 4.1, the map ν
+follows from (5.1) and is an isomorphism by [ADCKP], and the right vertical
+map is the identification induced by the pull-back via the extended Torelli
+
+20
+N. TARASCA
+map as in Proposition 2.4. From [ADCKP, 4.10.iv], one has λ = −ν [α].
+Hence, (5.2) follows.
+Furthermore, one has a commutative diagram
+(5.5)
+H2 (sp (H′) ⋉ H′, C)
+H2 �
+�
+Xg, C
+�
+H2 (Witt ⋉ H′, C)
+H2 �
+�Pg−1, C
+�
+µ
+σ∗
+µ
+where the map σ∗ is the injection studied in Proposition 4.1, the map µ
+follows from (5.1) and is an isomorphism by [ADCKP], and the right vertical
+map is the inclusion induced by the pull-back via the extended Torelli map
+as in Proposition 2.4. From [ADCKP, 4.10], one has λ = −µ [α] and θ =
+−µ [ψ]. Applying the description of σ∗ from Proposition 4.1, (5.3) follows.
+□
+As an immediate consequence, we obtain:
+Corollary 5.2.
+(i) For g ≥ 3, the line bundle Λ on �
+Ag carries an action
+of mp (H′) by first-order differential operators extending the transitive
+action of sp (H′) on �
+Ag and with the central element 1 ∈ mp (H′) acting
+as multiplication by 2 on the fibers of Λ → �
+Ag.
+(ii) For g ≥ 3, the line bundle Θ on
+�
+Xg carries an action of
+�
+U2(H)
+by first-order differential operators extending the transitive action of
+sp (H′) ⋉ H′ on �
+Xg and with the central element 1 ∈ �
+U2(H) acting as
+multiplication by −1 on the fibers of Θ → �
+Xg.
+Proof. The statement follows from (5.2), (5.3), and Remark 4.2.
+□
+The spaces and line bundles appearing in the statement are summarized
+by the commutative diagram:
+(5.6)
+Λ
+Θ
+Λ
+Θ
+�
+Ag
+�
+Xg
+�
+Mg
+�Pg−1
+where the left and right squares are Cartesian. This diagram provides a
+geometric counterpoint to Figure 1. The conclusions of Corollary 5.2 are
+summarized by the following diagrams. Let (Z, F, L) → S be a family of
+extended abelian varieties over a smooth base S. Recall that Proposition
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 21
+4.3 gives the splitting spF (H′) ֒→ mp (H′). Let FΛ be the Atiyah algebra
+of the line bundle Λ on �
+Ag, i.e., the sheaf of first-order differential operators
+acting on Λ. Corollary 5.2 implies the following commutative diagram of
+sheaves of Lie algebras with exact rows and columns:
+(5.7)
+OS
+OS
+spF (H′ (OS))
+mp (H′ (OS))
+FΛ|S
+spF (H′ (OS))
+sp (H′ (OS))
+TS.
+1
+2
+=
+Similarly, consider a family (Z, F, L, h, q) → S over a smooth base S as
+in §2.4. Proposition 4.3 gives the splitting spF (H′) ⋉ F ֒→ �
+U2(H). Let FΘ
+be the Atiyah algebra of the line bundle Θ on �
+Xg. Corollary 5.2 implies the
+following commutative diagram of sheaves of Lie algebras with exact rows
+and columns:
+(5.8)
+OS
+OS
+spF (H′ (OS)) ⋉ F (OS)
+�
+U2 (H (OS))
+FΘ|S
+spF (H′ (OS)) ⋉ F (OS)
+sp (H′ (OS)) ⋉ H′ (OS)
+TS.
+−1
+=
+6. Intermezzo on vertex algebras
+Here we comment on the vertex operator algebras and their properties
+required in the following sections. We refer to [FHL, Kac] for more details.
+A vertex operator algebra is a Z≥0-graded complex vector space V to-
+gether with a distinguished degree-0 element 1, a distinguished degree-2
+element ω, and a linear map Y ( , t): V → End(V )�t, t−1�, satisfying suitable
+conditions. The Fourier coefficients of Y (ω, t) realize an action of the Vira-
+soro algebra on V . This action is said to be of central charge c ∈ C if the
+Virasoro operators on V satisfy
+[Lp, Lq] = (p − q) Lp+q + c
+12 (p3 − p) δp+q,0 idV
+for p, q ∈ Z.
+In the following, we will consider vertex operator algebras for which the
+action of the Virasoro algebra extends to an action of the metaplectic algebra
+(recall the inclusion (1.11)). For this, let V be a vertex operator algebra
+admitting an embedding π → V , where π is the rank one Heisenberg vertex
+algebra with conformal vector 1
+2 b2
+−1. Note that any nonzero map π → V
+of vertex operator algebras is necessarily an embedding. The embedding
+
+22
+N. TARASCA
+π → V induces an action of the Heisenberg algebra H(C) on V , which in
+turn induces an action of the Weyl algebra �
+U (H(C)) on V . This restricts
+to an action
+(6.1)
+�
+U2(H(C)) → End(V ).
+Composing with the inclusion from (1.9), we deduce an action
+(6.2)
+mp
+�
+H′(C)
+�
+→ End(V ).
+By the defining conditions of vertex operator algebras, the element L0 of
+the Virasoro algebra acts on V as the grading operator, and the element bi
+of the Heisenberg algebra acts on V as an operator of the degree −i, for
+i ∈ Z. Via the inclusion (1.11), L0 is realized in the metaplectic algebra
+as 1
+2
+�
+i̸=0 b−i bi. Hence, the action of 1
+2
+�
+i̸=0 b−i bi on V is diagonalizable
+with integral eigenvalues. We will sometime need a stronger property:
+Definition 6.1. A Heisenberg–admissible vertex algebra is a vertex operator
+algebra V admitting an embedding π → V such that the resulting action of
+b−i bi on V is diagonalizable with integral eigenvalues for i ≥ 1.
+For instance, Heisenberg vertex algebras of arbitrary rank and even lattice
+vertex algebras are Heisenberg–admissible vertex algebras.
+We will also use the following characterization:
+Definition 6.2. For a vertex operator algebra V , an embedding π → V
+is said to be of central charge c ∈ C if it induces an action of Vir on V of
+central charge c. A Heisenberg–admissible vertex algebra V is said to be of
+central charge c if the embedding π → V is of central charge c.
+7. Coinvariants on families of extended abelian varieties
+We define here spaces of coinvariants at extended abelian varieties and
+show how these yield twisted D-modules on �
+Ag.
+Using results from §5,
+we identify a multiple of the Atiyah algebra of the line bundle Λ on �
+Ag
+which acts on the sheaves of coinvariants and thus determines their twisted
+D-module structure. Similarly, we define and study twisted D-modules of
+coinvariants on �
+Xg.
+7.1. Spaces of coinvariants at extended PPAVs. Let (Z, F, L) be an
+extended abelian variety over a C-algebra R.
+A vertex operator algebra
+V admitting an embedding π → V carries an action of mp (H′(C)) as in
+(6.2). This action extends R-linearly to an action of mp (H′(R)) on V ⊗C R.
+Composing with the splitting spF (H′) ֒→ mp (H′) from Proposition 4.3, one
+has an action of spF (H′(R)) on V ⊗C R. We define the space of coinvariants
+of V at (Z, F, L) as
+�V(V )(Z,F,L) := V ⊗C R / spF
+�
+H′(R)
+�
+(V ⊗C R) .
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 23
+7.2. Sheaves of coinvariants on �
+Ag. The spaces of coinvariants induce
+sheaves of coinvariants as follows.
+Let (Z, F, L) → S be a family of ex-
+tended abelian varieties over a smooth base S.
+A vertex operator alge-
+bra V admitting an embedding π → V carries an action of mp (H′(C)) as
+in (6.2) which extends OS-linearly to an action of the sheaf of Lie alge-
+bras mp (H′(OS)) on the sheaf V ⊗C OS. This action restricts to an ac-
+tion of the sheaf of Lie algebras spF (H′(OS)) on V ⊗C OS via the splitting
+spF (H′(OS)) ֒→ mp (H′(OS)) as in (5.7). We define the sheaf of coinvari-
+ants of V on (Z, F, L) → S as the quasi-coherent sheaf of OS-modules
+�V(V )(Z,F,L)→S := V ⊗C OS
+�
+spF
+�
+H′(OS)
+�
+(V ⊗C OS) .
+This gives rise to a quasi-coherent sheaf �V(V ) on �
+Ag.
+Theorem 7.1. For a vertex operator algebra V with an embedding π → V
+of central charge c, the sheaf �V(V ) on �
+Ag carries an action of the Atiyah
+algebra c
+2 FΛ. This action induces a twisted D-module structure on �V(V ).
+Proof. The action of mp (H′(C)) on V as in (6.2) and the action of mp (H′)
+on �
+Ag via the projection mp (H′) → sp (H′) induce an action of the sheaf
+of Lie algebras mp (H′(OS)) on the sheaf V ⊗C OS. While it is not OS-
+linear, this action extends the OS-linear action of spF (H′(OS)) on V ⊗C OS
+since spF (H′) acts trivially on �
+Ag. Applying the central row of (5.7), the
+action of mp (H′(OS)) factors to an action of the Atiyah algebra α FΛ on
+�V(V ), for some α ∈ C. Since the central element 1 of mp (H′) acts on V as
+multiplication by the central charge c, the first row of (5.7) implies α = c
+2,
+hence the statement.
+□
+7.3. Sheaves of coinvariants on �
+Xg. Let (Z, F, L, h, q) → S be a family
+as in §2.4 over a smooth base S. A vertex operator algebra V admitting an
+embedding π → V carries an action of �
+U2(H(C)) as in (6.1). This extends
+OS-linearly to an action of the sheaf of Lie algebras �
+U2(H(OS)) on the sheaf
+V ⊗C OS. Composing with the splitting
+spF
+�
+H′(OS)
+�
+⋉ F(OS) ֒→ �
+U2(H(OS))
+as in (5.8), one has an action of spF (H′(OS))⋉F(OS) on V ⊗COS. We define
+the sheaf of coinvariants of V on (Z, F, L, h, q) → S as the quasi-coherent
+sheaf of OS-modules
+�V(V )(Z,F,L,h,q)→S := V ⊗C OS
+� �
+spF
+�
+H′(OS)
+�
+⋉ F (OS)
+�
+(V ⊗C OS) .
+This gives rise to a quasi-coherent sheaf �V(V ) on �
+Xg.
+Theorem 7.2. For a vertex operator algebra V with an embedding π → V
+of central charge c, the sheaf �V(V ) on �
+Xg carries an action of the Atiyah
+algebra −c FΘ. This action induces a twisted D-module structure on �V(V ).
+
+24
+N. TARASCA
+Proof. The action of �
+U2(H(C)) on V as in (6.1) and the action of �
+U2(H) on
+�
+Xg via the projection �
+U2(H) → sp (H′) ⋉ H′ induce an action of the sheaf
+of Lie algebras �
+U2(H(OS)) on the sheaf V ⊗C OS.
+Applying the central
+row of (5.8), this action factors to an action of the Atiyah algebra α FΘ
+on �V(V ), for some α ∈ C. Since the central element 1 of �
+U2(H) acts on
+V as multiplication by c, the first row of (5.8) implies α = −c, hence the
+statement.
+□
+7.4. Coinvariants from arbitrary modules. More generally, the results
+of this section extend to the case of coinvariants obtained from modules of
+vertex operator algebras. Namely, let V be a vertex operator algebra with
+an embedding π → V , and let M be a V -module (as in [FHL]). For a family
+(Z, F, L) → S of extended abelian varieties over a smooth base S, the sheaf
+of Lie algebras spF (H′(OS)) acts on M ⊗C OS. The quasi-coherent sheaf of
+OS-modules
+�V(M)(Z,F,L)→S := M ⊗C OS
+�
+spF
+�
+H′(OS)
+�
+(M ⊗C OS)
+gives rise to a quasi-coherent sheaf �V(M) on �
+Ag. This carries an action of
+the Atiyah algebra c
+2 FΛ, where c is the central charge of π → V .
+Similarly, for a family (Z, F, L, h, q) → S as in §2.4 over a smooth base
+S, the sheaf of Lie algebras spF (H′(OS)) ⋉ F(OS) acts on M ⊗C OS. The
+quasi-coherent sheaf of OS-modules
+�V(M)(Z,F,L,h,q)→S := M ⊗C OS
+� �
+spF
+�
+H′(OS)
+�
+⋉ F (OS)
+�
+(M ⊗C OS)
+gives rise to a quasi-coherent sheaf �V(M) on �
+Xg which carries an action of
+the Atiyah algebra −c FΘ.
+8. Coinvariants on families of abelian varieties
+Here we construct twisted D-modules of coinvariants on Ag by descending
+the twisted D-modules �V(V ) from §7 along the projection �
+Ag → Ag. We
+proceed similarly on Xg.
+We use the following splittings. It is immediate to see that the two-cocycle
+on sp (H′) defining mp (H′) from (1.6) vanishes on the Lie algebra sp+ (H′)
+from §3.1, hence one has a Lie algebra splitting
+(8.1)
+sp+ �
+H′�
+֒→ mp
+�
+H′�
+.
+Similarly, the two-cocycle on sp (H′)⋉H′ defining �
+U2(H) from (1.8) vanishes
+on sp+ (H′) ⋉ H′
++, hence one has a Lie algebra splitting
+(8.2)
+sp+ �
+H′�
+⋉ H′
++ ֒→ �
+U2(H).
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 25
+8.1. The action of Sp+ (H′). Let V be a vertex operator algebra admitting
+an embedding π → V . From Theorem 7.1, the sheaf �V(V ) on �
+Ag carries
+an action of the Atiyah algebra c
+2 FΛ, where c is the central charge of the
+embedding π → V . This is induced by an action of mp (H′) on �V(V ) via the
+projection mp (H′) → c
+2 FΛ. Composing with the inclusion (8.1), we deduce
+an action of sp+ (H′) on the sheaf �V(V ) on �
+Ag. Next, we show:
+Proposition 8.1. For a Heisenberg–admissible vertex algebra V , the action
+of sp+ (H′) on the sheaf �V(V ) on �
+Ag can be exponentiated to an equivariant
+action of Sp+ (H′) on �V(V ).
+Proof. Recall from §3.2 that since Sp+ (H′) is connected, elements in
+Sp+ (H′) are products of exponentials of elements in sp+ (H′).
+Hence it
+is enough to show that the action on �V(V ) of exponentials of elements in
+sp+ (H′) is well-defined.
+By definition, sp+ (H′) is topologically generated by elements of type
+bi bj ∈ S2(H′) with i, j not both negative. As the degree of the operator
+bi on V is −i, the degree of bi bj on V is −(i + j), for bi bj ∈ sp+ (H′). In
+particular, �S2(H′
++) ⊂ sp+ (H′) acts on V by operators of negative degree,
+hence �S2(H′
++) acts locally nilpotently on V . This implies that the action of
+�S2(H′
++) on V ⊗C OS can be exponentiated, since the formula for the action
+of exponentials of elements in �S2(H′
++) is locally a finite sum.
+Next, consider bi bj with i > 0 and j < 0. If i + j > 0, then the degree
+of bi bj on V is still negative, hence bi bj acts locally nilpotently on V . If
+i + j < 0, then the degree of bi bj on V is positive; however, bi and bj com-
+mute, and the degree of bi is negative, hence bi bj still acts locally nilpotently
+on V , and thus this action can be exponentiated.
+Then, consider the case bi bj with i + j = 0.
+Since V is Heisenberg–
+admissible, the action of bi bj on V is diagonalizable with integral eigenvalues
+by definition. This action can be exponentiated to an action of the multi-
+plicative group scheme Gm on V by letting a ∈ Gm act as multiplication by
+ak on the eigenspace of bi bj with eigenvalue k.
+Finally, we discuss the case of an arbitrary element of sp+ (H′).
+For
+(Z, F, L) in �
+Ag, Theorem 2.2 implies that spF (H′) is preserved by the action
+of sp+ (H′). After quotienting by spF (H′), the Lie algebra sp+ (H′) factors
+to �S2(H′
++)×
+�
+H′
++ ⊗ Z/F
+�
+as in (3.1), thus the action of sp+ (H′) on V ⊗COS
+factors to an action of �S2(H′
++)×
+�
+H′
++ ⊗ Z/F
+�
+on �V(V ). This implies that for
+an arbitrary element of sp+ (H′), only finitely many terms bi bj with i+j ≤ 0
+act locally non-trivially on �V(V ).
+Using the arguments in the previous
+paragraphs, one checks that the formula for the action of exponentials of
+elements in sp+ (H′) with only finitely many terms bi bj with i + j ≤ 0 is
+locally a finite sum on �V(V ). The statement follows.
+□
+
+26
+N. TARASCA
+8.2. Sheaves of coinvariants on Ag. Let V be a Heisenberg–admissible
+vertex algebra. From Proposition 8.1, the sheaf �V(V ) on �
+Ag carries an equi-
+variant action of Sp+ (H′). From Theorem 3.1, Sp+ (H′) acts transitively on
+the fibers of the map �
+Ag → Ag. It follows that the quotient of �V(V ) by the
+action of Sp+ (H′) descends along the projection �
+Ag → Ag to a sheaf on Ag,
+which we call the sheaf of coinvariants V(V ) on Ag. One has a Cartesian
+diagram
+(8.3)
+�V(V )
+V(V )
+�
+Ag
+Ag.
+Applying Theorem 7.1, we are now ready for:
+Proof of Theorems 1 and 2. From Theorem 7.1, the sheaf �V(V ) on �
+Ag car-
+ries an action of the Atiyah algebra c
+2 FΛ. Since this action is compatible
+with the action of Sp+ (H′), it induces an action of the Atiyah algebra c
+2 FΛ
+on the sheaf V(V ) on Ag, hence the statements.
+□
+Example 8.2. When c = 0, the action of the Atiyah algebra factors to an
+action of the tangent sheaf to Ag on the sheaf of coinvariants V(V ) on Ag.
+Hence for c = 0, the sheaf V(V ) is more simply a D-module on Ag.
+8.3. The action of Sp+ (H′) ⋉ O×
+1 . Next, we discuss how to construct
+similarly sheaves of coinvariants on Xg. For this, we start describing the
+action of Sp+ (H′) ⋉ O×
+1 on the sheaf of coinvariants on �
+Xg.
+Let V be a vertex operator algebra admitting an embedding π → V . From
+Theorem 7.2, the sheaf �V(V ) on �
+Xg carries an action of the Atiyah algebra
+−c FΘ, where c is the central charge of the embedding π → V . This is
+induced by an action of �
+U2(H) on �V(V ) via the projection �
+U2(H) → −c FΛ.
+Composing with the inclusion (8.2), we deduce an action of sp+ (H′) ⋉ H′
++
+on the sheaf �V(V ) on �
+Xg.
+Proposition 8.3. For a Heisenberg–admissible vertex algebra V , the action
+of sp+ (H′)⋉H′
++ on the sheaf �V(V ) on �
+Xg can be exponentiated to an action
+of Sp+ (H′) ⋉ O×
+1 on �V(V ).
+The statement follows similarly to Proposition 8.1, since elements in
+Sp+ (H′) ⋉ O×
+1 are products of exponentials of elements in sp+ (H′) ⋉ H′
++,
+and H′
++ acts locally nilpotently on V .
+8.4. Sheaves of coinvariants on Xg. For a Heisenberg–admissible vertex
+algebra V , Proposition 8.3 gives an equivariant action of Sp+ (H′) ⋉ O×
+1
+on the sheaf �V(V ) on �
+Ag. Since from Theorem 3.3, Sp+ (H′) ⋉ O×
+1 acts
+transitively on the fibers of the map �
+Xg → Xg, it follows that �V(V ) descends
+along the projection �
+Xg → Xg to a sheaf on Xg, which we call the sheaf of
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 27
+coinvariants V(V ) on Xg. One has a Cartesian diagram as in (8.3), with
+�
+Ag → Ag replaced by �
+Xg → Xg.
+Proof of Theorems 3 and 4. From Theorem 7.2, the sheaf �V(V ) on �
+Xg car-
+ries an action of the Atiyah algebra −c FΘ. Since this action is compatible
+with the action of Sp+ (H′)⋉O×
+1 , it induces an action of the Atiyah algebra
+−c FΘ on the sheaf V(V ) on Xg, hence the statements.
+□
+9. Final remarks
+9.1. Geography of Harish-Chandra pairs. The constructions of the
+sheaves of coinvariants in §8 are variations on the formalism of localization
+of modules over Harish-Chandra pairs first introduced in [BB] and further
+developed in [BFM, BS] and [FBZ, §17.2]. A Harish-Chandra pair (g, K)
+consists of a Lie algebra g and a Lie group K verifying some compatibility
+conditions. The localization functor assigns to a module over (g, K), i.e.,
+a vector space with compatible actions of g and K, a (possibly twisted)
+D-module on a variety identified by the Harish-Chandra pair. For instance,
+localizations of: modules over (Der (O) , Aut (O)) (see notation from §3.4)
+yield D-modules on a smooth curve; modules over (Witt, Aut (O)) yield D-
+modules on the moduli space Mg,1 of pointed smooth curves of genus g; and
+modules over (Vir, Aut (O)) yield twisted D-modules on Mg,1. We refer to
+[FBZ] for a discussion of these and more geometries.
+The construction of the twisted D-modules of coinvariants on Ag and Xg
+in §8 can be interpreted as the result of the localization of modules over the
+Harish-Chandra pairs
+�
+mp
+�
+H′�
+, Sp+ �
+H′��
+and
+�
+�
+U2(H), Sp+ �
+H′�
+⋉ O×
+1
+�
+,
+respectively. We emphasize a difference here with respect to the geometry
+of curves: While the group Aut (O) acts simply transitively on the fibers of
+�
+Mg → Mg,1, the group Sp+ (H′) acts transitively, but not simply, on the
+fibers of �
+Ag → Ag, as discussed in §3.
+9.2. Comparison with classical coinvariants on curves. For a vertex
+operator algebra V , the space of coinvariants at (C, P, t) ∈ �
+Mg constructed
+in [FBZ] is the quotient of V by the action of a Lie algebra LC\P (V ) de-
+pending on both V and the open subset C \ P ⊂ C. The kernel of the map
+Witt → T(C,P,t)( �
+Mg) is a Lie subalgebra of LC\P (V ), but in general is not
+equal to it. It is shown in [FBZ] how the construction globalizes over �
+Mg
+and yields an Aut (O)-equivariant twisted D-module on �
+Mg. This thus de-
+scends along the principal Aut (O)-bundle �
+Mg → Mg,1. Furthermore, since
+the resulting fibers at (C, P) and (C, Q) in Mg,1 are canonically isomorphic
+for all P, Q ∈ C, the sheaf is constant along the fibers of Mg,1 → Mg and
+thus descends to a twisted D-module on Mg.
+
+28
+N. TARASCA
+For a vertex operator algebra V admitting an embedding π → V , the
+space of coinvariants at (Z, F, L) ∈ �
+Ag from §7 is the quotient of V by the
+action of the Lie algebra spF (H′). Contrary to LC\P(V ), the Lie algebra
+spF (H′) is independent of V and equals the kernel of the analogous map
+sp (H′) → T(Z,F,L)( �
+Ag), hence it is the smallest Lie algebra whose coinvari-
+ants yield twisted D-modules on �
+Ag. This implies that the push-forward via
+the Torelli embedding Mg → Ag of the sheaf of coinvariants for LC\P(V )
+on Mg does not map to the sheaf of coinvariants for spF (H′) on Ag for a
+general V . For this, it is natural to determine a Lie algebra containing as
+Lie subalgebras both spF (H′) and LC\P (V ) at points in the Jacobian locus.
+We will present such an extension in a follow-up work.
+The spaces of coinvariants for LC\P (V ) are known to have finite dimension
+when V satisfies some finiteness and semisimplicity conditions [AN, DGT2],
+and thus give rise to vector bundles of coinvariants on Mg whose Chern
+classes are determined by their twisted D-module structure [DGT1].
+It
+would be interesting to determine a similar result on spaces of coinvariants
+on Ag. The mentioned extension of spF (H′) will provide a better context
+for investigating this property, which we intend to explore accordingly.
+9.3. Failing descent for arbitrary modules. Spaces of coinvariants for
+LC\P(V ) have been constructed also for the action of LC\P(V ) on an ar-
+bitrary V -module [FBZ].
+These give rise to twisted D-modules on Mg,1
+[DGT2, §8.7], which in general do not descend on Mg. In fact, the descent
+along Mg,1 → Mg is only possible after tensoring the sheaf of coinvariants
+by an appropriate power of the relative cotangent line bundle to offset the
+variation of the spaces of coinvariants along the fibers of Mg,1 → Mg (as
+in [DGT2, §8.7]).
+Similarly, the twisted D-modules of coinvariants from
+arbitrary V -modules constructed in §7.4 in general do not descend on Ag.
+As the relative H2-space for the map �
+Ag → Ag is trivial (Proposition 2.4),
+tensoring by a line bundle will not help here. It would be interesting to find
+a finite-dimensional extension of the moduli space Ag where the sheaves of
+coinvariants from arbitrary modules could descend from �
+Ag.
+References
+[ADC]
+E. Arbarello and C. De Concini. Abelian varieties, infinite dimensional Lie alge-
+bras, and the heat equation. In Proceedings of Symposia in Pure Mathematics,
+volume 53, 1991. ↑1, ↑2, ↑3, ↑8, ↑9, ↑10, ↑11, ↑12, ↑13, ↑14, ↑16
+[ADCK]
+E. Arbarello, C. De Concini, and V. Kac. The infinite wedge representation and
+the reciprocity law for algebraic curves. In Theta functions—Bowdoin, volume
+49, Part 1, pages 171–190. American Mathematical Society, 1987. ↑3, ↑4
+[ADCKP] E. Arbarello, C. De Concini, V. G. Kac, and C. Procesi. Moduli spaces of
+curves and representation theory. Comm. Math. Phys., 117(1):1–36, 1988. ↑3,
+↑10, ↑12, ↑13, ↑14, ↑16, ↑17, ↑19, ↑20
+[AN]
+T. Abe and K. Nagatomo. Finiteness of conformal blocks over compact Rie-
+mann surfaces. Osaka J. Math., 40(2):375–391, 2003. ↑28
+
+COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 29
+[BB]
+A. Beilinson, A. and J. Bernstein. A proof of Jantzen conjectures. In I. M.
+Gelfand Seminar, volume 16 of Adv. Soviet Math., pages 1–50. Amer. Math.
+Soc., Providence, RI, 1993. ↑27
+[BD]
+A. Beilinson and V. Drinfeld. Quantization of Hitchin’s integrable system
+and Hecke eigensheaves. Preprint, available at http://math.uchicago.edu/ drin-
+feld/langlands/QuantizationHitchin.pdf, 1991. ↑3, ↑14, ↑15
+[BFM]
+A. Beilinson, B. Feigin, and B. Mazur. Introduction to algebraic field theory
+on curves. Unpublished, 1991. ↑27
+[BS]
+A. A. Beilinson and V. V. Schechtman. Determinant bundles and Virasoro
+algebras. Comm. Math. Phys., 118(4):651–701, 1988. ↑2, ↑27
+[BZN]
+D. Ben-Zvi and T. Nevins. W-symmetry of the ad`elic Grassmannian. Commu-
+nications in Mathematical Physics, 293(1):185–204, 2010. ↑1
+[DGT1]
+C. Damiolini, A. Gibney, and N. Tarasca. Conformal blocks from vertex alge-
+bras and their connections on Mg,n. Geometry & Topology, 25(5):2235–2286,
+2021. ↑28
+[DGT2]
+C. Damiolini, A. Gibney, and N. Tarasca. On factorization and vector bundles of
+conformal blocks from vertex algebras. Annales Scientifiques de l’ ´Ecole Normale
+Sup´erieure, to appear, arXiv:1909.04683, 2022. ↑28
+[FBZ]
+E. Frenkel and D. Ben-Zvi. Vertex algebras and algebraic curves, volume 88
+of Mathematical Surveys and Monographs. Am Mathem Soc, Providence, RI,
+second edition, 2004. ↑1, ↑3, ↑6, ↑7, ↑12, ↑14, ↑15, ↑27, ↑28
+[FHL]
+I. B. Frenkel, Y.-Z. Huang, and J. Lepowsky. On axiomatic approaches to ver-
+tex operator algebras and modules. Mem. Amer. Math. Soc., 104(494):viii+64,
+1993. ↑21, ↑24
+[FP]
+R. Fringuelli and R. Pirisi. The Picard group of the universal abelian variety
+and the Franchetta conjecture for abelian varieties. Michigan Mathematical
+Journal, 68(3):651–671, 2019. ↑12
+[FS]
+E. Frenkel and M. Szczesny. Twisted modules over vertex algebras on algebraic
+curves. Advances in Mathematics, 187(1):195–227, 2004. ↑1
+[Hai]
+R. Hain. Moduli of Riemann surfaces, transcendental aspects. In School on
+Algebraic Geometry (Trieste, 1999), pages 293–353. Abdus Salam Int. Cent.
+Theoret. Phys., Trieste. ↑12
+[Kac]
+V. Kac. Vertex algebras for beginners, volume 10 of University Lecture Series.
+Am Mathem Soc, Providence, RI, 1997. ↑21
+[TUY]
+A. Tsuchiya, K. Ueno, and Y. Yamada. Conformal field theory on universal
+family of stable curves with gauge symmetries. In Integrable systems in quantum
+field theory and statistical mechanics, volume 19 of Adv. Stud. Pure Math.,
+pages 459–566. Academic Press, Boston, MA, 1989. ↑1
+[VDG]
+G. Van Der Geer. The cohomology of the moduli space of abelian varieties. In
+Handbook of Moduli I, volume 24 of Advanced Lectures in Mathematics, pages
+415–458. International Press of Boston, Inc., 2013. ↑12
+Nicola Tarasca
+Department of Mathematics & Applied Mathematics
+Virginia Commonwealth University, Richmond, VA 23284
+Email address: tarascan@vcu.edu
+
diff --git a/ytFQT4oBgHgl3EQfBjWV/content/tmp_files/load_file.txt b/ytFQT4oBgHgl3EQfBjWV/content/tmp_files/load_file.txt
new file mode 100644
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+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf,len=1009
+page_content='arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='13227v1  [math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='AG]  30 Jan 2023  COINVARIANTS OF VERTEX ALGEBRAS  ON MODULI OF ABELIAN VARIETIES  NICOLA TARASCA  Abstract.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a vertex operator algebra with Heisenberg symmetries,  we construct spaces of coinvariants at principally polarized abelian va-  rieties with respect to the action of an infinite-dimensional Lie algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We show how these spaces globalize to twisted D-modules on moduli  of principally polarized abelian varieties, and we determine the Atiyah  algebra of a line bundle acting on them.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We prove analogous results on  the universal abelian variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Introduction  Spaces of coinvariants have classically been constructed by assigning rep-  resentations of affine Lie algebras, and more generally, vertex operator al-  gebras, to algebraic curves [TUY, FBZ].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' These spaces globalize to quasi-  coherent sheaves carrying a twisted D-module structure on moduli of curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Said structure is induced by an equivariant action of the Virasoro algebra on  vertex operator algebra modules and on moduli of curves with marked points  and formal coordinates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The construction generalizes to produce twisted D-  modules on moduli spaces parametrizing pointed curves with extra features:  line bundles, principal bundles, and D-bundles [FS, FBZ, BZN].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Removing curves out of the picture, Arbarello–De Concini [ADC] con-  structed a moduli space �  Ag of suitable extensions of principally polarized  abelian varieties which includes, via an extended Torelli map, the moduli  space �  Mg of algebraic curves with a marked point and a formal coordinate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  They showed that an infinite-dimensional symplectic algebra sp (H′) acts  transitively on �  Ag, extending the transitive action of the Witt algebra on  �  Mg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Here, H′ is the Lie subalgebra of the infinite-dimensional Heisenberg  algebra consisting of elements with zero constant term.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The oscillator rep-  resentation which injects the Witt algebra into sp (H′) thus appears as the  differential of the extended Torelli map.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The present project started from the realization that the results of [ADC]  offer an opening for an extension of the classical conformal field theory  from moduli spaces of curves to moduli spaces of abelian varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Remov-  ing curves out of the construction of coinvariants, we thus build and study  twisted D-modules on moduli spaces of abelian varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Our construction proceeds as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a vertex operator algebra V  admitting an embedding of the rank one Heisenberg vertex algebra π → V ,  MSC2020.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  14K10, 17B65, 17B66, 17B69, 14F06 (primary), 14K25, 14L15 (secondary).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Key words and phrases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Infinite-dimensional Lie algebras, moduli of abelian varieties,  symplectic and metaplectic algebras, connections and Atiyah algebras, vertex operator  algebras, Heisenberg symmetries, sheaves of coinvariants, conformal field theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1  2  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  we define the space of coinvariants of V at a point a ∈ �  Ag as  (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  �V(V )a := V / spF  �  H′�  V,  where spF (H′) is the stabilizer of sp (H′) at a—see (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The space (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  is the largest quotient of V on which spF (H′) acts trivially.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We show that  the spaces (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) globalize to a sheaf �V(V ) on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Furthermore, in case V is  Heisenberg–admissible, as per Definition 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, we show that the sheaf �V(V )  descends on the moduli space Ag of principally polarized, g-dimensional  abelian varieties:  Theorem 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex algebra V , the spaces of  coinvariants (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) give rise to a twisted D-module V(V ) on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For instance, the theorem applies to Heisenberg vertex algebras of ar-  bitrary rank and even lattice vertex algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The metaplectic algebra  mp (H′)—reviewed in §1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4—acts on �  Ag via the projection mp (H′) → sp (H′)  and on V thanks to the embedding π → V and replaces the Virasoro algebra  of the classical conformal field theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' These actions induce the twisted D-  module structure on V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' To explicitly determine it, we use the formalism  of Atiyah algebras from Beilinson-Schechtman [BS].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let Λ be the Hodge line  bundle on Ag, and FΛ the Atiyah algebra of Λ, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', the sheaf of first-order  differential operators acting on Λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We say that a Heisenberg–admissible  vertex algebra V is of central charge c if the embedding π → V induces an  action of the Virasoro algebra on V of central charge c—see §6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex algebra V of central charge  c, the sheaf V(V ) on Ag carries an action of the Atiyah algebra c  2 FΛ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This  action induces the twisted D-module structure on V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Moreover, we extend these results over the universal abelian variety.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is  shown in [ADC] that �  Ag admits a universal family �  Xg → �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This extends  the universal family Xg over the stack Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The space �  Xg carries a transitive  action of the Lie algebra sp (H′) ⋉ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We define the space of coinvariants  of V at x ∈ �  Xg as  (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  �V(V )x := V /  �  spF  �  H′�  ⋉ F  �  V,  where spF (H′) ⋉ F is the stabilizer of sp (H′) ⋉ H′ at x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex algebra V , the spaces of  coinvariants (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) give rise to a twisted D-module V(V ) on Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The twisted D-module structure is explicitly determined by the action of  an appropriate multiple of the Atiyah algebra FΘ of the theta line bundle  Θ on Xg:  Theorem 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex algebra V of central charge  c, the sheaf V(V ) on Xg carries an action of the Atiyah algebra −c FΘ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This  action induces the twisted D-module structure on V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES  3  To prove the above statements, we need to show some auxiliary results,  which are of independent interest.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is shown in [ADCKP] that for g ≥ 3,  there are canonical isomorphisms  H2 (Witt, C) ∼= H2 (Mg, C) ,  H2 �  Witt ⋉ H′, C  � ∼= H2 �  P′  d, C  �  ,  where Mg is the moduli space of smooth genus g curves, and P′  d is the moduli  space of quadruples (C, P, v, L ), where C is a smooth genus g curve, P is  a point of C, v is a nonzero tangent vector to C at P, and L is a degree d  line bundle on C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We show that these isomorphisms extend to give:  Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For g ≥ 3, one has canonical isomorphisms  H2 �  sp  �  H′�  , C  � ∼= H2 (Ag, C) ,  H2 �  sp  �  H′�  ⋉ H′, C  � ∼= H2 (Xg, C) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Moreover, we study group (ind)-schemes of symplectic automorphisms  in §3, generalizing the group (ind)-schemes of ring automorphisms from  [BD, FBZ].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Our constructions of the sheaves of coinvariants on Ag and Xg  are thus variations on the formalism of localization of modules over Harish-  Chandra pairs (§9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The present results are intended to initiate the study  of coinvariants on abelian varieties and their moduli.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We mention some  natural directions in §9 and will return to these in the near future.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The paper is structured as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We review the algebraic and geometric  background in §§1 and 2, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In §3 we define and study a group  scheme which acts transitively on the fibers of the natural map �  Ag → Ag,  together with related group (ind-)schemes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In §4 we start the study of the  cohomology of the Lie algebras sp (H′) and sp (H′) ⋉ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In §5 we prove  Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, which establishes two canonical isomorphisms of H2 spaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 5 follows from Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1 and Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2  we describe the Atiyah algebras of the Hodge and theta line bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Next,  an intermezzo in §6 contains a review of vertex algebras and their required  properties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We construct sheaves of coinvariants on �  Ag and �  Xg in §7 and  descend them on Ag and Xg in §8, where we prove Theorems 1–4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We  conclude with some final remarks in §9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Throughout, we work over C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Heisenberg, metaplectic, and Virasoro algebras  We review here the infinite-dimensional Lie algebras from [ADCK, ADC]  which will play a role in the paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The complex Lie algebras from these  references are here promoted to functors on commutative C-algebras, as  needed for our geometric constructions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Moreover, emphasis is given to the  two-cocycles defining the relevant central extensions, later needed in §§4–5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Here is some notation used throughout.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a topological vector space V ,  a subset B ⊂ V is said to topologically generate V if finite linear combina-  tions of elements of B form a dense open subspace of V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Also, let gl(V ) be  the Lie algebra of continuous linear endomorphisms of V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  4  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The algebra of formal Laurent series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let H be the functor which  assigns to a C-algebra R the R-algebra H(R) := R((t)) of formal Laurent  series in a parameter t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has a decomposition  H = H+ ⊕ H−,  where  H+(R) := R�t�  and  H−(R) := t−1R[t−1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Also, let H′ be the functor which assigns to R the R-module H′(R) ⊂ H(R)  of Laurent series with zero constant term:  H′ := H′  + ⊕ H−  where H′  + := t H+.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The R-module H(R) is endowed with the t-adic topology.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This is the  topology that has the collection of cosets  �  f + tNH+ | f ∈ H and N ≥ 1  �  as a basis of open subsets.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This gives H the structure of a complete topo-  logical space, topologically generated over R by bi := ti for i ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We will repeatedly use the following result from [ADCK]: the Lie algebra  gl(H) has a canonical two-cocycle given by  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  ψ (A, B) := Tr (π+ A π− B π+ − π+ B π− A π+)  for A, B ∈ gl(H),  where π+ : H → H+ and π− : H → H− are the natural projections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Heisenberg algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Consider the symplectic form ⟨ , ⟩ on H  given by  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  ⟨f, g⟩ := − Res  t=0 f dg  for f, g ∈ H.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This only depends on df and dg, for f, g ∈ H, and restricts to a nondegener-  ate symplectic form on H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Heisenberg algebra is the Lie algebra struc-  ture on H given by the Lie bracket ⟨ , ⟩.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' As (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) is continuous with respect  to the t-adic topology, the Heisenberg algebra H is a complete topological  Lie algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Moreover, (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) is invariant by changes of the parameter t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Note that ⟨f, g⟩ = ψ(f, g), where ψ is from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1), and f, g ∈ H act on H by  multiplication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Thus, the Heisenberg algebra H is the central extension  0 → gl1 1 → H → H′ → 0  given be the restriction of the two-cocycle ψ, where 1 := b0, and gl1 is the  functor assigning to a C-algebra R the trivial Lie algebra R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The enveloping algebra U (H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let U (H) be the quotient of the  universal enveloping algebra of the Heisenberg algebra H by the two-sided  ideal generated by 1 − 1, where 1 is the central element of H, and 1 is the  unit in the universal enveloping algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The algebra U (H) has a canonical  filtration U0(H) ⊂ U1(H) ⊂ · · · , where U0(H) = gl1 1, and UN(H) for  N ∈ N assigns to a C-algebra R the R-module generated by the products  f1 · · · fm with m ≤ N and fi ∈ H for i ≤ N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES  5  Remarkably, U2(H) is a Lie subalgebra of U (H) for the Lie bracket given  by the commutator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Explicitly, the Lie bracket in U2(H) is given by  [f, g] = ⟨f, g⟩,  [f, 1] = [fg, 1] = 0,  [fg, k] = ⟨f, k⟩ g + ⟨g, k⟩ f,  [fg, kl] = ⟨g, k⟩ fl + ⟨f, k⟩ gl + ⟨g, l⟩ kf + ⟨f, l⟩ kg  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3)  for f, g, k, l ∈ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has  U2(H)/gl1 1 ∼= S2(H′) ⋉ H′  as Lie algebras, where S2(H′) is the second symmetric power of H′, and the  semidirect product is given by the action of S2(H′) on H′ induced by  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4)  fg: H′ → H′,  k �→ ⟨f, k⟩ g + ⟨g, k⟩ f,  for f, g, k ∈ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence, U2(H) is a central extension  0 → gl1 1 → U2(H) → S2(H′) ⋉ H′ → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  To identify the corresponding two-cocycle, arguing by cases, one shows that  [: fg :, : kl :]  =  −1  2 ψ (fg, kl) 1  +⟨g, k⟩ : fl : +⟨f, k⟩ : gl : +⟨g, l⟩ : kf : +⟨f, l⟩ : kg :  in U2(H) is compatible with (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3), where : : denotes the normal order prod-  uct giving a specific lift of elements from S2(H′) to U2(H), and ψ is the  restriction of the two-cocycle in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence, the two-cocycle c defining  U2(H) is given by  c(fg, kl) = −1  2 ψ (fg, kl) ,  c(f, g) = ⟨f, g⟩,  c(fg, k) = 0  for f, g, k, l ∈ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We will need a completion of U2(H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For this, we first introduce the  completion of S2(H′) given by the symplectic algebra and its corresponding  extension.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Symplectic and metaplectic algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The symplectic algebra sp (H′)  is the Lie subalgebra of gl(H′) defined as  sp  �  H′�  :=  �  X ∈ gl(H′) | ⟨Xa, b⟩ + ⟨a, Xb⟩ = 0, for all a, b ∈ H′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The action of S2(H′) on H′ induced by (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4) realizes S2(H′) as a dense Lie  subalgebra of sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The metaplectic algebra mp (H′) is the central extension  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5)  0 → gl1 1 → mp  �  H′�  → sp  �  H′�  → 0  defined by the two-cocycle  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6)  − 1  2 ψ (X, Y )  for X, Y ∈ sp (H′)  where ψ is the restriction of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  6  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Weyl algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Weyl algebra  �  U (H) is the completion of  the algebra U (H) with respect to the topology in which the basis of open  neighborhoods of 0 is formed by the left ideals of the submodules  tNH+ ⊂ H ⊂ �  U (H)  for N ∈ Z  [FBZ, §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Elements of �  U (H) can be described as possibly infinite series  of the form A0 + �  i≥1 Ai bi with Ai equal to a finite linear combination of  finite formal products of elements in {bj}j∈Z for i ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The closure �  U2(H) of U2(H) in �  U (H) is a complete topological Lie sub-  algebra of �  U (H) for the Lie bracket given by the commutator.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Explicitly,  consider first the semidirect product sp (H′) ⋉ H′ given by the action  [X, f] = X(f)  for X ∈ sp (H′) and f ∈ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence, the Lie bracket for sp (H′) ⋉ H′ is  [X + f, Y + g] = XY − Y X + X(g) − Y (f)  for X, Y ∈ sp (H′) and f, g ∈ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Then, one has a central extension  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7)  0 → gl1 1 → �  U2(H) → sp  �  H′�  ⋉ H′ → 0  with two-cocycle c given by  c(X, Y ) = −1  2 ψ (X, Y ) ,  c(f, g) = ⟨f, g⟩,  c(X, f) = 0  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8)  for X, Y ∈ sp (H′) and f, g ∈ H′, where ψ is the restriction of (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This is  compatible with the Lie bracket for U2(H) in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The metaplectic algebra mp (H′) is realized as a Lie subalgebra of �  U2(H)  via the injection  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='9)  mp  �  H′�  ֒→ �  U2(H),  1 �→ 1,  X �→ X  for X ∈ sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Witt and Virasoro algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Witt algebra Witt is the functor  assigning to a C-algebra R the Lie algebra R((t))∂t of continuous deriva-  tions of R((t)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is topologically generated over R by Lp := −tp+1∂t for  p ∈ Z, with relations [Lp, Lq] = (p − q)Lp+q for p, q ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The oscillator  representation of Witt gives an injection of Lie algebras  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10)  τ : Witt ֒→ sp  �  H′�  ,  Lp �→ 1  2  �  i  b−i bi+p  where the sum is over i ∈ Z \\ {0, −p}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The Virasoro algebra Vir is the central extension  0 → gl1 1 → Vir → Witt → 0  with Lie bracket given by  [Lp, Lq] = (p − q) Lp+q + 1  12 (p3 − p) δp+q,0 1,  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES  7  mp (H′)  �  U2(H)  Vir  D  sp (H′)  sp (H′) ⋉ H′  Witt  Witt ⋉ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  �τ  �σ  τ  σ  Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The main Lie algebra maps.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  where δp+q,0 = 1 when p + q = 0, and δp+q,0 = 0 otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The two-cocycle  defining this extension is the restriction over Witt of the two-cocycle (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The map τ is lifted by the injection  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11)  �τ : Vir ֒→ mp  �  H′�  ,  Lp �→ 1  2  �  i  : b−i bi+p :,  1 �→ 1  where the sum is over i ∈ Z \\ {0, −p}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The map σ and the Lie algebra D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We will need the Lie algebra  injection  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='12)  σ: Witt ⋉ H′ ֒→ sp  �  H′�  ⋉ H′,  Lp �→ 1  2  �  i  b−i bi+p − p + 1  2  bp,  bq �→ bq  where the sum is over i ∈ Z \\ {0, −p}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For p = 0, one simply has  L0 �→ 1  2  �  i b−i bi, since b0 vanishes in H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Remark 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' There are infinitely many ways of injecting Witt ⋉ H′ in  sp (H′) ⋉ H′: by replacing in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='12) the coefficient − p+1  2  with a(p + 1)  for a ∈ C, one obtains a one-parameter family of such injections, as in the  Segal-Sugawara construction [FBZ, 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The case a = − 1  2 is specifically  needed in §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Finally, let D be the central extension  0 → gl1 1 → D → Witt ⋉ H′ → 0  defined by the restriction to Witt ⋉ H′ of the two-cocycle ψ from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) such  that Witt acts on H as in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10) and H′ acts on H by multiplication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The  map σ is lifted by the injection  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='13)  �σ: D ֒→ �  U2(H),  Lp �→ 1  2  �  i  : b−i bi+p : − p + 1  2  bp,  bq �→ bq,  1 �→ 1  where the sum is over i ∈ Z \\ {0, −p}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  8  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  The main Lie algebra maps of this section are summarized by the com-  mutative diagram in Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' There, the four horizontal surjections admit  Lie algebra splittings, and the left and right squares are Cartesian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Extended abelian varieties and their moduli  First, we review some geometric constructions and results from [ADC] re-  lated to suitable extensions of abelian varieties and their moduli.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Theorems  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 play a key role in later sections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Then, we conclude with a review  of the degree-2 cohomology classes on the moduli spaces in consideration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Extended abelian varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Recall the symplectic form ⟨ , ⟩ on H′  from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  An extended principally polarized abelian variety (extended  PPAV, for short) of dimension g is a triple (Z, F, L), where  Z is a Lagrangian subspace of H′,  F is a codimension g subspace of Z, and  L is a rank 2g lattice in F ⊥/F,  satisfying four suitable conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The form ⟨ , ⟩ on H′ induces a nonde-  generate symplectic form on F ⊥/F, which will still be denoted as ⟨ , ⟩.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The  first three conditions imposed on the triple (Z, F, L) are:  Z ∩ H′  + = 0,  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  LR ∩ A = 0  where  LR := L ⊗Z R  and  A := F ⊥ ∩ H′  +,  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  1  2πi ⟨ , ⟩ is unimodular on L.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3)  Condition (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) implies the decompositions  H′ = Z ⊕ H′  +  and  F ⊥/F = Z/F ⊕ A  into maximal isotropic subspaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It follows that F ⊥/F has dimension 2g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Condition (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) implies that: the projection F ⊥/F → Z/F induces a real  isomorphism LR ∼= Z/F;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' the real structure on F ⊥/F induced by LR identi-  fies A with the conjugate of Z/F;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' and the form on Z/F given by  B(u, v) := 1  π ⟨u, v⟩  for u, v ∈ Z/F  is Hermitian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The fourth and last condition on the triple (Z, F, L) is  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4)  the form B on Z/F is positive definite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  A triple (Z, F, L) satisfying the four conditions (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)-(2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4) determines an  abelian variety X, which is the quotient of the g-dimensional space Z/F by  the image of L under the projection F ⊥/F → Z/F, equipped with the po-  larization B, which is principal by (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' More precisely, the triple (Z, F, L)  is equivalent to an isomorphism class of extensions  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5)  0 → H′  + → H′/K → X → 0  where K is the preimage of L under the projection F ⊥ → F ⊥/F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES  9  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Moduli of extended PPAVs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In [ADC], the set  �  Ag of extended  PPAVs of dimension g is endowed with the structure of an infinite-  dimensional analytic manifold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We sketch here the construction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Consider  the infinite-dimensional analytic manifold  �  Hg := �S2(H′  +) × Bg(H′  +) × Hg  where  �S2 �  H′  +  �  :=  �  ϕ: H− → H′  +  �����  ϕ is linear and symmetric,  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', ⟨a, ϕ(b)⟩ = ⟨ϕ(a), b⟩ for all a, b ∈ H−  �  ,  Bg(H′  +) := the manifold of frames of (H′  +)g,  Hg := the Siegel upper half-space of degree g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The symplectic group Sp(2g, Z) acts freely and properly discontinuously on  �  Hg, hence the quotient �  Hg / Sp(2g, Z) has a natural structure of an infinite-  dimensional analytic manifold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Moreover, one has a bijection of sets  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6)  �  Hg / Sp(2g, Z) → �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence, (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6) induces on �  Ag the structure of an infinite-dimensional analytic  manifold [ADC, §3].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has a commutative diagram  �  Hg  �  Ag  Hg  Ag  / Sp(2g,Z)  / Sp(2g,Z)  where Ag is the moduli space of principally polarized abelian varieties of  dimension g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The action of Sp(2g, Z) on Hg has finite nontrivial stabilizers,  hence at least an orbifold structure is required on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Here we consider Ag as  the resulting quotient stack.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This is a separated, smooth Deligne-Mumford  stack.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From [ADC], �  Ag is rational homotopy equivalent to Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Remark 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' To treat  �  Ag and Ag on an equal footing, we will consider  families (Z, F, L) → S of extended PPAVs of dimension g over a smooth  scheme S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We will construct sheaves of coinvariants on such families in §7  and descend them to families of PPAVs in §8, thus yielding sheaves on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Symplectic uniformization of moduli of extended PPAVs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' An  action of a Lie algebra g on a variety X over C is a homomorphism of Lie  algebras g → Vect(X), where Vect(X) is the Lie algebra of regular vector  fields on X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The action is said to be transitive if for every x ∈ X, the  evaluation map g → Tx(X) is surjective.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 (Uniformization of �  Ag [ADC]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The moduli space �  Ag carries  a transitive action of sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For (Z, F, L) in �  Ag, one has  T(Z,F,L)  �  �  Ag  �  ∼= spF  �  H′�  \\ sp  �  H′�  10  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  where  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7)  spF  �  H′�  :=  �  X ∈ sp  �  H′�  | X  �  F ⊥�  ⊆ F  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We sketch the proof from [ADC]: using the map (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6), and since the  action of Sp(2g, Z) on �  Hg is properly discontinuous, one deduces  T(Z,F,L)  �  �  Ag  �  ∼= �S2 �  H′  +  �  ×  �  H′  + ⊗ Z/F  �  × S2 (Z/F) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This is then shown to be isomorphic to spF (H′) \\ sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We emphasize  that the subspace  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8)  �S2(H′  +) ×  �  H′  + ⊗ Z/F  �  is the tangent space to the fiber of the forgetful map �  Ag → Ag at (Z, F, L).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The universal extended PPAV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The moduli space �  Ag admits a  universal family �  Xg → �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The fiber over a point (Z, F, L) in �  Ag is  �  H′/K  �  ×G Q  where G is the group of points of order 2 in H′/K, and Q is the G-torsor  of integral quadratic forms q on L satisfying  q(a) + q(b) − q(a + b) ≡  1  2πi ⟨a, b⟩  mod 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The need for the twist by G becomes clear when one defines the maps in  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Points of �  Xg are denoted as (Z, F, L, h, q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The map �  Xg → �  Ag has  no zero-section, however the fiber over (Z, F, L) in �  Ag is non-canonically  isomorphic to H′/K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From [ADC], �  Xg is rational homotopy equivalent to  the universal family Xg over the stack Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' More generally, we will consider  families (Z, F, L, h, q) → S over a smooth scheme S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Uniformization of the universal extended PPAV.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Recall the Lie  algebra sp (H′) ⋉ H′ from §1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 (Uniformization of �  Xg [ADC]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The moduli space �  Xg carries  a transitive action of sp (H′) ⋉ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For (Z, F, L, h, q) in �  Xg, one has  T(Z,F,L,h,q)  �  �  Xg  �  ∼= spF  �  H′�  ⋉ F \\ sp  �  H′�  ⋉ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The case of curves and line bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The moduli spaces �  Ag and  �  Xg are naturally extensions of moduli spaces of curves and line bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' To  see this, let �  Mg be the moduli space of triples (C, P, t), where C is a smooth  genus g curve, P is a point of C, and t is a formal coordinate at P [ADCKP].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  From [ADC], there is an extended Torelli map �  Mg → �  Ag mapping (C, P, t)  to a triple (Z, F, L) with identifications  F ∼= H0 (C \\ P, OC) ,  Z/F ∼= H1 (C, OC) ,  L ∼= H1 (C, Z) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The isotropicity of F with respect to (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) follows from the residue theorem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 11  Moreover, let �Pd → �  Mg be the relative Picard variety parametrizing  isomorphism classes of quintuples (C, P, t, L , ϕ) where L is a line bundle of  degree d on C and ϕ is a trivialization of the restriction of L to the formal  disc around P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For d = g − 1, one has a commutative diagram  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='9)  �Pg−1  �  Xg  �  Mg  �  Ag  where (C, P, t, L , ϕ) in �Pg−1 is mapped to (Z, F, L, h, q) in �  Xg such that q is  arbitrary in Q, and h is the unique point of H′/K given by the isomorphism  class of  �  L η−1, ϕ dt− 1  2  �  , where η is the unique theta-characteristic on C  identified by q via Riemann’s theorem [ADC, (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='23)].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' By the construction  of �  Xg, this map is independent of the choice of q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Recall the commutative diagram  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10)  Witt ⋉ H′  sp (H′) ⋉ H′  Witt  sp (H′)  σ  τ  from Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is shown in [ADC, (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11)] that the Lie algebras in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10)  act transitively on the corresponding moduli spaces in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='9), and the maps  in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10) induce the differentials of the corresponding maps in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='9).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Hodge and theta line bundles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Here we review the degree-2  cohomology classes on the moduli spaces in consideration.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let Λ → Ag be  the Hodge line bundle defined by  Λ := det  �  π∗  �  ωXg/Ag  ��  where π: Xg → Ag is the natural projection and ωXg/Ag is the relative dual-  izing sheaf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let Θ → Xg be the relative theta line bundle whose restriction to  the fibers of π induces the principal polarization on each fiber.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For simplic-  ity, we omit the notation for the pull-back when referring to the pull-back  of Λ and Θ via the nature projections �  Ag → Ag and �  Xg → Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let λ and θ  be the first Chern classes of Λ and Θ, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For g ≥ 2, one has  H2 �  �  Ag, Z  �  = H2 (Ag, Z) = Zλ,  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11)  H2 �  �  Xg, Z  �  = H2 (Xg, Z) = Zλ ⊕ Zθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='12)  Moreover, for g ≥ 3, the pull-back via the extended Torelli map induces an  identification  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='13)  H2( �  Ag, Z) =  −→ H2 �  �  Mg, Z  �  = H2 (Mg, Z)  12  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  and an inclusion  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='14)  H2 �  �  Xg, Z  �  ⊂ H2 �  �Pg−1, Z  �  = H2 �  P′  g−1, Z  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The statement combines various results from the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For g ≥ 2, one has H2(Ag, Z) = Zλ, and for g ≥ 3, the Torelli map  induces an identification H2(Ag, Z) = H2(Mg, Z) (e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', [VDG, 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1] and [Hai,  17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3–17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The last identity fails for g = 2, since H2(M2, Z) is generated  by λ but cyclic of order 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since Ag and �  Ag have the same rational homotopy type [ADC, pg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' 16–  17], (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11) follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Similarly, Xg and �  Xg have the same rational homotopy  type [ADC, pg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' 17], hence the first isomorphism in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='12).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The second  identification in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='12) follows from [FP].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Next, consider the composition of forgetful maps  (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='15)  �  Mg → M′  g → Mg  where M′  g is the moduli space of triples (C, P, v), where C is a curve of  genus g, P is a point of C, and v is a nonzero tangent vector to C at P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since �  Mg and M′  g have the same rational homotopy type and  H2(M′  g, Z) = H2(Mg, Z) = Zλ  [ADCKP, 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8], the composition of the maps in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='15) induces an identifica-  tion H2( �  Mg, Z) = Zλ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Using (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11), we deduce (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='13).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Note that the class  of the cotangent line bundle at the marked point vanishes on M′  g and �  Mg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Finally,  �Pg−1 and P′  g−1 have the same rational homotopy type and  H2(P′  g−1, Z) is described in [ADCKP, 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7]: it has dimension three, and  λ and θ are linearly independent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The inclusion (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='14) follows, hence the  statement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Group (ind-)schemes of symplectic automorphisms  Here we study how to exponentiate the symplectic algebra sp (H′) and  related Lie algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We use group ind-schemes as in [FBZ, §A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For  a topological vector space E, let GL(E) be the group of continuous linear  automorphisms of E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Also, for a topological group G, let G◦ be its connected  component of the identity.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Lie algebra sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let sp+ (H′) be the Lie subalgebra of  sp (H′) which preserves the subspace H′  +, that is:  sp+ �  H′�  :=  �  X ∈ sp  �  H′�  | X(H′  +) ⊆ H′  +  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This has the following geometric incarnation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Recall from (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8) that for  (Z, F, L) in �  Ag, the tangent space to the fiber of the forgetful map �  Ag → Ag  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 13  at (Z, F, L) is �S2 �  H′  +  �  ×  �  H′  + ⊗ Z/F  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has a natural quotient of Lie  algebras  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  sp+ �  H′�  ։ �S2 �  H′  +  �  ×  �  H′  + ⊗ Z/F  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The transitive action of sp (H′) on �  Ag from §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 extends the transitive ac-  tion of sp+ (H′) along the fibers of the forgetful map �  Ag → Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Hence, the  symplectic uniformization of �  Ag induces the following double coset realiza-  tion of the tangent space of Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For (Z, F, L) ∈ �  Ag, let (X, B) ∈ Ag be the  image of (Z, F, L) via �  Ag → Ag as in (2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  T(X,B) (Ag) ∼= spF  �  H′�  \\ sp  �  H′�  / sp+ �  H′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The group scheme Sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We will need to exponentiate the Lie  algebra sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For this, consider the group scheme of continuous sym-  plectic automorphisms of H′ preserving the subspace H′  +, and let Sp+ (H′)  be its connected component of the identity, that is:  Sp+ �  H′�  :=  �  ρ ∈ GL(H′)  �����  ⟨ρ(a), ρ(b)⟩ = ⟨a, b⟩  for all a, b ∈ H′,  ρ  �  H′  +  �  ⊆ H′  +  � .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The group scheme Sp+ (H′) represents the group functor which assigns  to a C-algebra R the identity component Sp+ (H′(R)) of the group of  continuous symplectic automorphisms of H′(R) preserving the subspace  H′  +(R) = tR�t�.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  One easily checks that  Lie(Sp+ �  H′)  �  = sp+ �  H′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Also, since Sp+ (H′) is by definition connected, elements in Sp+ (H′) are  products of exponentials of elements in sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The adjoint action of the group scheme Sp+ (H′) on sp+ (H′) induces a  transitive action of Sp+ (H′) on the fibers of �  Ag → Ag, and Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 as  shown in [ADC] can be recasted as:  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1 (after [ADC]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The moduli space �  Ag carries a transitive ac-  tion of sp (H′) compatible with the transitive action of Sp+ (H′) on the fibers  of �  Ag → Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Remark 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' As the group GL(H) is not connected [ADCKP, pg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' 11], taking  the identity component in the definition of Sp+ (H′) can not be omitted  without modifying the outcome.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The group ind-scheme Sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' More generally, consider the group  functor which assigns to a C-algebra R the connected group Sp (H′(R)) of  continuous linear automorphisms of H′(R) of the following type  Sp  �  H′(R)  �  :=  �  ρ ∈ GL(H′(R))  �����  ⟨ρ(a), ρ(b)⟩ = ⟨a, b⟩  for all a, b ∈ H′,  ρ  �  H′  +(R)  �  ⊆ H′  +(R) ⊕ H−(Rn)  � 14  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  where Rn ⊆ R is the C-subalgebra consisting of nilpotent elements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The  presence of nilpotent elements entails that this functor can only be repre-  sented by an ind-scheme, as schemes are insufficient (this is as in [FBZ,  §6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Let Sp (H′) be the group ind-scheme representing this functor.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Naturally, Sp+ (H′) is a subgroup of Sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One checks that  Lie  �  Sp  �  H′��  = sp  �  H′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Derivations and ring automorphisms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Here we remark how the Lie  algebras and group (ind-)schemes of this section naturally extend analogous  objects studied in [BD, FBZ] and related to the geometry of curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Namely,  let Der(O) be the functor assigning to a C-algebra R the Lie algebra  Der (O(R)) = R�t�∂t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This is the Lie subalgebra of the Lie algebra Witt(R) from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6) topologically  generated over R by Lp for p ≥ −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The inclusion τ : Witt ֒→ sp (H′) from  (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10) maps Der (O) to sp+ (H′), so that one has a commutative diagram of  Lie algebras  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3)  Witt  sp (H′)  Der (O)  sp+ (H′) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  τ  From [ADCKP], the moduli space �  Mg carries a transitive action of Witt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This action is compatible with a simply transitive action of Der (O) on the  fibers of �  Mg → Mg: the elements Lp with p ≥ 0 topologically generate the  tangent directions to the changes of the formal coordinate at the marked  point, and the element L−1 spans the tangent space to the curve at the  marked point.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Hence, for (C, P, t) in �  Mg, one has  (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4)  TC (Mg) ∼= Vect(C \\ P) \\ Witt / Der (O) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  From [ADC], the moduli space �  Ag carries a transitive action of sp (H′) and  by factoring Witt and sp (H′) by appropriate Lie subalgebras, the inclusion  τ induces the differential of the extended Torelli map �  Ag → �  Mg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We emphasize how the transitive action of sp+ (H′) on the fibers of  �  Ag → Ag is naturally the extension of the simply transitive action of Der (O)  on the fibers of �  Mg → Mg, and (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) extends (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  One has a similar picture for the related group (ind-)schemes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Namely,  consider first the group scheme Aut (O) representing the functor which as-  signs to a C-algebra R the group of continuous ring automorphisms of R�t�  preserving the ideal tR�t�.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Explicitly, this is:  Aut (O(R)) :=  �  t �→ a1 t + a2 t2 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' | ai ∈ R and a1 is a unit  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since the symplectic form (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) is invariant by changes of the parameter t  and tR�t� = H′  +(R) as vector spaces, it follows that Aut (O) is a subgroup of  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 15  Sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' However, the Lie algebra of Aut (O) is smaller than Der (O): As  remarked in [FBZ, §6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3], one has Lie (Aut (O)) = t Der (O), and in order  to exponentiate Der (O), one needs to consider a group ind-scheme.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For this,  let Aut (O) be the group ind-scheme representing the functor which assigns  to a C-algebra R the group of continuous ring automorphisms of R�t�:  Aut (O(R)) :=  �  t �→ a0 + a1 t + a2 t2 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  �����  ai ∈ R, a1 is a unit,  and a0 is nilpotent  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Similarly, let Aut (K) be the group ind-scheme representing the functor  which assigns to a C-algebra R the group of continuous ring automorphisms  of R((t)):  Aut (K(R)) :=  \uf8f1  \uf8f2  \uf8f3t �→  �  i≥i0  ai ti  �����  ai ∈ R, a1 is a unit,  ai nilpotent for i ≤ 0  \uf8fc  \uf8fd  \uf8fe .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  One has  Lie (Aut (O)) = Der (O)  and  Lie (Aut (K)) = Witt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We refer to [BD, FBZ] for more on Der (O), Aut (O) and Aut (K).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Elements in Aut (O) and Aut (K) naturally induce elements in GL(H),  and after composing with the projection H → H′, they induce symplectic  elements in GL(H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Hence, one has a commutative diagram of group (ind)-  schemes  Aut (K)  Sp (H′)  Aut (O)  Sp+ (H′)  such that the differentials of these maps restricted to the tangent spaces at  the identities are given by (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The group ind-scheme Mp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We will also consider the group  ind-scheme Mp (H′) given by the central extension  1 → Gm → Mp  �  H′�  → Sp  �  H′�  → 1  corresponding to the metaplectic algebra mp (H′) from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The group scheme Sp+ (H′) ⋉ O×  1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Finally, we describe the analo-  gous Lie algebras and group (ind)-schemes for the moduli space �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The  transitive action of sp (H′) ⋉ H′ on �  Xg from §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5 extends a transitive action  of sp+(H′) ⋉ H′  + on the fibers of �  Xg → Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let O×  1 be the group scheme  of invertible Taylor series with constant term 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This is a subgroup of the  group scheme O× of invertible Taylor series from [FBZ, §20.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has  Lie (O×) = H+ and Lie  �  O×  1  �  = H′  +.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  16  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 (after [ADC]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The moduli space �  Xg carries a transitive ac-  tion of sp (H′) ⋉ H′ compatible with the transitive action of Sp+ (H′) ⋉ O×  1  on the fibers of �  Xg → Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' On the cohomology of the Lie algebras  Here we study the cohomology of the Lie algebras sp (H′) and sp (H′)⋉H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We will then show in Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1 that their H2 spaces are canonically  isomorphic to H2 (Ag, C) and H2 (Xg, C), respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For a topological Lie algebra g, let H∗(g, C) be its continuous Lie algebra  cohomology with complex coefficients.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Recall the two-cocycle ψ of gl(H) from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1), and consider the two-  cocycles on sp (H′) ⋉ H′  α (X + f, Y + g) := ψ(X, Y ),  β (X + f, Y + g) := ψ(f, g) = −Rest=0 f dg,  γ (X + f, Y + g) := ψ(X, g) − ψ(Y, f)  for X, Y ∈ sp (H′) and f, g ∈ H′, where f, g act on H by multiplication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence, ψ = α + β + γ on sp (H′) ⋉ H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Restricting to Witt ⋉ H′, one has  α (f∂t + g, h∂t + k) = 1  6 Rest=0 f dh′′,  γ (f∂t + g, h∂t + k) = −1  2 Rest=0  �  f dk′ − h dg′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Similarly, consider the two-cocycle α(X, Y ) := ψ(X, Y ) on sp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is  shown in [ADCKP, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1] that H1 (Witt, C) = H1 (Witt ⋉ H′, C) = 0, and  H2 (Witt, C) = C α  and  H2 �  Witt ⋉ H′, C  �  = C α ⊕ C β ⊕ C γ  where α is the class of α, and similarly for β and γ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Recall τ : Witt ֒→ sp (H′)  from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10) and σ: Witt ⋉ H′ ֒→ sp (H′) ⋉ H′ from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='12).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has  H1 �  sp  �  H′�  , C  �  = 0,  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  H1 �  sp  �  H′�  ⋉ H′, C  �  = 0,  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  H2 �  sp  �  H′�  , C  �  = C α,  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3)  H2 �  sp  �  H′�  ⋉ H′, C  �  = C α ⊕ C β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4)  Moreover, the pull-back via τ induces the identification  τ ∗ : H2 �  sp  �  H′�  , C  � =  −→ H2 (Witt, C) ,  and the pull-back via σ induces the injection  σ∗ : H2 �  sp  �  H′�  ⋉ H′, C  �  ֒→ H2 �  Witt ⋉ H′, C  �  ,  α �→ α,  β �→ 1  2 α + ψ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 17  Remark 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The two-cocycle defining the central extension mp (H′) of  sp (H′) in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6) is − 1  2 α.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Also, the two-cocycle defining the central extension  �  U2(H) of sp (H′) ⋉ H′ in (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8) is − 1  2 α + β.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let H′  f be the functor which assigns to a C-algebra R the R-  subalgebra H′  f(R) := R[t, t−1] ⊂ H′(R).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One checks that  S2 �  H′  f  �  =  �  S2 �  H′  f  �  , S2 �  H′  f  ��  and  S2 �  H′  f  �  ⋉ H′  f =  �  S2 �  H′  f  �  ⋉ H′  f, S2 �  H′  f  �  ⋉ H′  f  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since H′  f is dense in H′ and S2 (H′) is dense in sp (H′), we deduce  sp  �  H′�  =  �  sp  �  H′�  , sp  �  H′��  and  sp  �  H′�  ⋉ H′ =  �  sp  �  H′�  ⋉ H′, sp  �  H′�  ⋉ H′�  hence (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) and (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) follow.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Next we prove (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Assume δ is an arbitrary two-cocycle on sp (H′)⋉H′.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Recall the relations  (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5)  [Lp, Lq] = (p − q) Lp+q,  [Lp, bq] = −q bp+q,  [bp, bq] = 0  on sp (H′) ⋉ H′, where Lp = −tp+1∂t and bq = tq for p, q ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Considering  terms of type  δ(Lp, [Lq, Lr]),  δ(Lp, [Lq, br]),  δ(Lp, [bq, br])  and imposing the two-cocycle relation  δ(x, [y, z]) + δ(y, [z, x]) + δ(z, [x, y]) = 0  for all x, y, z ∈ sp (H′) ⋉ H′ and the relations (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5), a direct computation as  in the proof of [ADCKP, 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1] shows that  δ (X + f, Y + g) ≡ A α (X + f, Y + g) + B β (X + f, Y + g)  + C γ (X + f, Y + g)  modulo coboundaries, for some A, B, C ∈ C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Next, consider the two-cocycle  relation for  x = b1b1,  y = b1b−2,  and  z = b−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Observe that  [b1b−2, b−1] = b−2,  [b−1, b1b1] = −2b1,  [b1b1, b1b−2] = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since  γ (b1b1, b−2) = 2  and  γ (b1b−2, b1) = 0,  it follows that the only non-trivial contribution to the two-cocycle relation  is C γ (b1b1, [b1b−2, b−1]) = 0, hence C = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A direct analysis shows that the  two-cocycle relations do not impose any relations on A and B, hence (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The identification in (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3) follows similarly from the argument for (4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For the final part of the statement, recall the map �σ : D ֒→  �  U2(H)  from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='13).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since the two-cocycle on Witt ⋉ H′ defining D is ψ, and  18  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  the two-cocycle on sp (H′) ⋉ H′ defining �  U2(H) is − 1  2 α + β, we deduce  σ∗ �  − 1  2 α + β  �  = ψ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A similar argument involving the map �τ from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11)  shows that σ∗(α) = τ ∗(α) = α, hence the statement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  For a topological Lie algebra g, the space H2(g, C) classifies Lie algebra  continuous central extensions of g up to isomorphism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Thus as a consequence  of the previous statement, we have:  Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let Z be a Lagrangian subspace of H′ with Z ∩ H′  + = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Every Lie algebra continuous central extension  0 → gl1 → �  sp (H′) → sp  �  H′�  → 0  —e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', mp (H′)—splits over spF (H′) for all F ⊂ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Similarly, every Lie  algebra continuous central extension  0 → gl1 →  �  sp (H′) ⋉ H′ → sp  �  H′�  ⋉ H′ → 0  —e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='g.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', �  U2(H)—splits over spF (H′) ⋉ F for all F ⊂ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One needs to show that the restriction of H2 (sp (H′) , C) to spF (H′)  (respectively, the restriction of H2 (sp (H′) ⋉ H′, C) to spF (H′) ⋉ F) van-  ishes for all F ⊂ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  From Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, it is enough to consider the  class of the two-cocycle α (resp.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', the classes of the two-cocycles α and β).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Also, after rescaling to − 1  2α as in Remark 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2, we can reduce to the case  �  sp (H′) = mp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For Z = H− and F ⊂ Z, one has F ⊂ H− ⊂ F ⊥, thus for X ∈ spF (H′),  one has  Im (π+ X π−) = π+ X(H−) ⊂ π+ X(F ⊥) ⊆ π+ F = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  It follows that for F ⊂ H−, one has α(X, Y ) = 0 for all X, Y in spF (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Next, consider an arbitrary Lagrangian subspace Z of H′ with Z ∩ H′  + = 0  and a subspace F ⊂ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2, the group scheme Sp+ (H′) acts transi-  tively on the space of such pairs (Z, F), hence there exists ρ ∈ Sp+ (H′) such  that (Z, F) = ρ(H−, F) for some F ⊂ H−.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let mpF (H′) be the restriction  of mp (H′) over spF (H′) and mpF (H′) the restriction over spF (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The  adjoint action of the group ind-scheme Mp (H′) on mp (H′) factors through  Sp (H′), hence  Ad ρ  �  spF  �  H′��  = spF  �  H′�  and  Ad ρ  �  mpF  �  H′��  = mpF  �  H′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since we have shown that mpF (H′) is a trivial extension, it follows that  mpF (H′) is a trivial extension, hence α(X, Y ) = 0 for all X, Y in spF (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The case of α on sp (H′) ⋉ H′ follows from α on sp (H′), and the case of  β follows immediately from F being isotropic with respect to (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 19  5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The isomorphism of second cohomology spaces  Consider a variety X over C carrying a transitive action of a Lie algebra  g (as defined in §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For x ∈ X, let gx := Ker(g → Tx(X)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is shown  in [ADCKP, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1] that if gx = [gx, gx] for all x ∈ X, then every Lie algebra  continuous central extension  0 → C → �g → g → 0  which splits over gx for all x ∈ X yields a continuous extension  0 → X × C → E → T(X) → 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This defines a canonical map  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  H2(g, C)0 → Ext1 (TX, OX) = H1 �  Ω1  X  �  where H2(g, C)0 ⊂ H2(g, C) is the subspace obtained by intersecting the  kernels of the restriction maps H2(g, C) → H2(gx, C) for all x ∈ X.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Combining Theorems 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 with Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3, the above result  from [ADCKP] applies to give canonical maps  ν : H2 �  sp  �  H′�  , C  �  → H2 �  �  Ag, C  �  ,  µ: H2 �  sp  �  H′�  ⋉ H′, C  �  → H2 �  �  Xg, C  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We determine these maps explicitly in terms of the basis elements of the H2  spaces given in Propositions 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4:  Theorem 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For g ≥ 3, one has  λ = −ν [α] ,  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  λ = −µ [α] ,  θ = 1  2 µ [α] − µ [β] .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3)  In particular, the maps µ and ν give canonical isomorphisms  H2 �  sp  �  H′�  , C  � ∼= H2 �  �  Ag, C  �  ,  H2 �  sp  �  H′�  ⋉ H′, C  � ∼= H2 �  �  Xg, C  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has a commutative diagram  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4)  H2 (sp (H′) , C)  H2 �  �  Ag, C  �  H2 (Witt, C)  H2 �  �  Mg, C  �  ν  =  τ ∗  =  ν  where the map τ ∗ is the identification studied in Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, the map ν  follows from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) and is an isomorphism by [ADCKP], and the right vertical  map is the identification induced by the pull-back via the extended Torelli  20  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  map as in Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From [ADCKP, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='iv], one has λ = −ν [α].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence, (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Furthermore, one has a commutative diagram  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='5)  H2 (sp (H′) ⋉ H′, C)  H2 �  �  Xg, C  �  H2 (Witt ⋉ H′, C)  H2 �  �Pg−1, C  �  µ  σ∗  µ  where the map σ∗ is the injection studied in Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, the map µ  follows from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) and is an isomorphism by [ADCKP], and the right vertical  map is the inclusion induced by the pull-back via the extended Torelli map  as in Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From [ADCKP, 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='10], one has λ = −µ [α] and θ =  −µ [ψ].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Applying the description of σ∗ from Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3) follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  As an immediate consequence, we obtain:  Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  (i) For g ≥ 3, the line bundle Λ on �  Ag carries an action  of mp (H′) by first-order differential operators extending the transitive  action of sp (H′) on �  Ag and with the central element 1 ∈ mp (H′) acting  as multiplication by 2 on the fibers of Λ → �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  (ii) For g ≥ 3, the line bundle Θ on  �  Xg carries an action of  �  U2(H)  by first-order differential operators extending the transitive action of  sp (H′) ⋉ H′ on �  Xg and with the central element 1 ∈ �  U2(H) acting as  multiplication by −1 on the fibers of Θ → �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The statement follows from (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2), (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3), and Remark 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  The spaces and line bundles appearing in the statement are summarized  by the commutative diagram:  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6)  Λ  Θ  Λ  Θ  �  Ag  �  Xg  �  Mg  �Pg−1  where the left and right squares are Cartesian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This diagram provides a  geometric counterpoint to Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The conclusions of Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 are  summarized by the following diagrams.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let (Z, F, L) → S be a family of  extended abelian varieties over a smooth base S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Recall that Proposition  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 21  4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 gives the splitting spF (H′) ֒→ mp (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let FΛ be the Atiyah algebra  of the line bundle Λ on �  Ag, i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', the sheaf of first-order differential operators  acting on Λ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 implies the following commutative diagram of  sheaves of Lie algebras with exact rows and columns:  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7)  OS  OS  spF (H′ (OS))  mp (H′ (OS))  FΛ|S  spF (H′ (OS))  sp (H′ (OS))  TS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  1  2  =  Similarly, consider a family (Z, F, L, h, q) → S over a smooth base S as  in §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 gives the splitting spF (H′) ⋉ F ֒→ �  U2(H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let FΘ  be the Atiyah algebra of the line bundle Θ on �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Corollary 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 implies the  following commutative diagram of sheaves of Lie algebras with exact rows  and columns:  (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8)  OS  OS  spF (H′ (OS)) ⋉ F (OS)  �  U2 (H (OS))  FΘ|S  spF (H′ (OS)) ⋉ F (OS)  sp (H′ (OS)) ⋉ H′ (OS)  TS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  −1  =  6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Intermezzo on vertex algebras  Here we comment on the vertex operator algebras and their properties  required in the following sections.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We refer to [FHL, Kac] for more details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  A vertex operator algebra is a Z≥0-graded complex vector space V to-  gether with a distinguished degree-0 element 1, a distinguished degree-2  element ω, and a linear map Y ( , t): V → End(V )�t, t−1�, satisfying suitable  conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Fourier coefficients of Y (ω, t) realize an action of the Vira-  soro algebra on V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This action is said to be of central charge c ∈ C if the  Virasoro operators on V satisfy  [Lp, Lq] = (p − q) Lp+q + c  12 (p3 − p) δp+q,0 idV  for p, q ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  In the following, we will consider vertex operator algebras for which the  action of the Virasoro algebra extends to an action of the metaplectic algebra  (recall the inclusion (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11)).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For this, let V be a vertex operator algebra  admitting an embedding π → V , where π is the rank one Heisenberg vertex  algebra with conformal vector 1  2 b2  −1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Note that any nonzero map π → V  of vertex operator algebras is necessarily an embedding.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The embedding  22  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  π → V induces an action of the Heisenberg algebra H(C) on V , which in  turn induces an action of the Weyl algebra �  U (H(C)) on V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This restricts  to an action  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  �  U2(H(C)) → End(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Composing with the inclusion from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='9), we deduce an action  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  mp  �  H′(C)  �  → End(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  By the defining conditions of vertex operator algebras, the element L0 of  the Virasoro algebra acts on V as the grading operator, and the element bi  of the Heisenberg algebra acts on V as an operator of the degree −i, for  i ∈ Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Via the inclusion (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='11), L0 is realized in the metaplectic algebra  as 1  2  �  i̸=0 b−i bi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Hence, the action of 1  2  �  i̸=0 b−i bi on V is diagonalizable  with integral eigenvalues.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We will sometime need a stronger property:  Definition 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A Heisenberg–admissible vertex algebra is a vertex operator  algebra V admitting an embedding π → V such that the resulting action of  b−i bi on V is diagonalizable with integral eigenvalues for i ≥ 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For instance, Heisenberg vertex algebras of arbitrary rank and even lattice  vertex algebras are Heisenberg–admissible vertex algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We will also use the following characterization:  Definition 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a vertex operator algebra V , an embedding π → V  is said to be of central charge c ∈ C if it induces an action of Vir on V of  central charge c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A Heisenberg–admissible vertex algebra V is said to be of  central charge c if the embedding π → V is of central charge c.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Coinvariants on families of extended abelian varieties  We define here spaces of coinvariants at extended abelian varieties and  show how these yield twisted D-modules on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Using results from §5,  we identify a multiple of the Atiyah algebra of the line bundle Λ on �  Ag  which acts on the sheaves of coinvariants and thus determines their twisted  D-module structure.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Similarly, we define and study twisted D-modules of  coinvariants on �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Spaces of coinvariants at extended PPAVs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let (Z, F, L) be an  extended abelian variety over a C-algebra R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  A vertex operator algebra  V admitting an embedding π → V carries an action of mp (H′(C)) as in  (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This action extends R-linearly to an action of mp (H′(R)) on V ⊗C R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Composing with the splitting spF (H′) ֒→ mp (H′) from Proposition 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3, one  has an action of spF (H′(R)) on V ⊗C R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We define the space of coinvariants  of V at (Z, F, L) as  �V(V )(Z,F,L) := V ⊗C R / spF  �  H′(R)  �  (V ⊗C R) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 23  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Sheaves of coinvariants on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The spaces of coinvariants induce  sheaves of coinvariants as follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Let (Z, F, L) → S be a family of ex-  tended abelian varieties over a smooth base S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  A vertex operator alge-  bra V admitting an embedding π → V carries an action of mp (H′(C)) as  in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) which extends OS-linearly to an action of the sheaf of Lie alge-  bras mp (H′(OS)) on the sheaf V ⊗C OS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This action restricts to an ac-  tion of the sheaf of Lie algebras spF (H′(OS)) on V ⊗C OS via the splitting  spF (H′(OS)) ֒→ mp (H′(OS)) as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We define the sheaf of coinvari-  ants of V on (Z, F, L) → S as the quasi-coherent sheaf of OS-modules  �V(V )(Z,F,L)→S := V ⊗C OS  �  spF  �  H′(OS)  �  (V ⊗C OS) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This gives rise to a quasi-coherent sheaf �V(V ) on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a vertex operator algebra V with an embedding π → V  of central charge c, the sheaf �V(V ) on �  Ag carries an action of the Atiyah  algebra c  2 FΛ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This action induces a twisted D-module structure on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The action of mp (H′(C)) on V as in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2) and the action of mp (H′)  on �  Ag via the projection mp (H′) → sp (H′) induce an action of the sheaf  of Lie algebras mp (H′(OS)) on the sheaf V ⊗C OS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' While it is not OS-  linear, this action extends the OS-linear action of spF (H′(OS)) on V ⊗C OS  since spF (H′) acts trivially on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Applying the central row of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7), the  action of mp (H′(OS)) factors to an action of the Atiyah algebra α FΛ on  �V(V ), for some α ∈ C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Since the central element 1 of mp (H′) acts on V as  multiplication by the central charge c, the first row of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7) implies α = c  2,  hence the statement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Sheaves of coinvariants on �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let (Z, F, L, h, q) → S be a family  as in §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4 over a smooth base S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A vertex operator algebra V admitting an  embedding π → V carries an action of �  U2(H(C)) as in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This extends  OS-linearly to an action of the sheaf of Lie algebras �  U2(H(OS)) on the sheaf  V ⊗C OS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Composing with the splitting  spF  �  H′(OS)  �  ⋉ F(OS) ֒→ �  U2(H(OS))  as in (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8), one has an action of spF (H′(OS))⋉F(OS) on V ⊗COS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We define  the sheaf of coinvariants of V on (Z, F, L, h, q) → S as the quasi-coherent  sheaf of OS-modules  �V(V )(Z,F,L,h,q)→S := V ⊗C OS  � �  spF  �  H′(OS)  �  ⋉ F (OS)  �  (V ⊗C OS) .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  This gives rise to a quasi-coherent sheaf �V(V ) on �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a vertex operator algebra V with an embedding π → V  of central charge c, the sheaf �V(V ) on �  Xg carries an action of the Atiyah  algebra −c FΘ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This action induces a twisted D-module structure on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  24  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The action of �  U2(H(C)) on V as in (6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1) and the action of �  U2(H) on  �  Xg via the projection �  U2(H) → sp (H′) ⋉ H′ induce an action of the sheaf  of Lie algebras �  U2(H(OS)) on the sheaf V ⊗C OS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Applying the central  row of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8), this action factors to an action of the Atiyah algebra α FΘ  on �V(V ), for some α ∈ C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Since the central element 1 of �  U2(H) acts on  V as multiplication by c, the first row of (5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8) implies α = −c, hence the  statement.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Coinvariants from arbitrary modules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' More generally, the results  of this section extend to the case of coinvariants obtained from modules of  vertex operator algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Namely, let V be a vertex operator algebra with  an embedding π → V , and let M be a V -module (as in [FHL]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a family  (Z, F, L) → S of extended abelian varieties over a smooth base S, the sheaf  of Lie algebras spF (H′(OS)) acts on M ⊗C OS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The quasi-coherent sheaf of  OS-modules  �V(M)(Z,F,L)→S := M ⊗C OS  �  spF  �  H′(OS)  �  (M ⊗C OS)  gives rise to a quasi-coherent sheaf �V(M) on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This carries an action of  the Atiyah algebra c  2 FΛ, where c is the central charge of π → V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Similarly, for a family (Z, F, L, h, q) → S as in §2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4 over a smooth base  S, the sheaf of Lie algebras spF (H′(OS)) ⋉ F(OS) acts on M ⊗C OS.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The  quasi-coherent sheaf of OS-modules  �V(M)(Z,F,L,h,q)→S := M ⊗C OS  � �  spF  �  H′(OS)  �  ⋉ F (OS)  �  (M ⊗C OS)  gives rise to a quasi-coherent sheaf �V(M) on �  Xg which carries an action of  the Atiyah algebra −c FΘ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Coinvariants on families of abelian varieties  Here we construct twisted D-modules of coinvariants on Ag by descending  the twisted D-modules �V(V ) from §7 along the projection �  Ag → Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We  proceed similarly on Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We use the following splittings.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is immediate to see that the two-cocycle  on sp (H′) defining mp (H′) from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='6) vanishes on the Lie algebra sp+ (H′)  from §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, hence one has a Lie algebra splitting  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1)  sp+ �  H′�  ֒→ mp  �  H′�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Similarly, the two-cocycle on sp (H′)⋉H′ defining �  U2(H) from (1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='8) vanishes  on sp+ (H′) ⋉ H′  +, hence one has a Lie algebra splitting  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2)  sp+ �  H′�  ⋉ H′  + ֒→ �  U2(H).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 25  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The action of Sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let V be a vertex operator algebra admitting  an embedding π → V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, the sheaf �V(V ) on �  Ag carries  an action of the Atiyah algebra c  2 FΛ, where c is the central charge of the  embedding π → V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This is induced by an action of mp (H′) on �V(V ) via the  projection mp (H′) → c  2 FΛ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Composing with the inclusion (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1), we deduce  an action of sp+ (H′) on the sheaf �V(V ) on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Next, we show:  Proposition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex algebra V , the action  of sp+ (H′) on the sheaf �V(V ) on �  Ag can be exponentiated to an equivariant  action of Sp+ (H′) on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Recall from §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 that since Sp+ (H′) is connected, elements in  Sp+ (H′) are products of exponentials of elements in sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence it  is enough to show that the action on �V(V ) of exponentials of elements in  sp+ (H′) is well-defined.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  By definition, sp+ (H′) is topologically generated by elements of type  bi bj ∈ S2(H′) with i, j not both negative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' As the degree of the operator  bi on V is −i, the degree of bi bj on V is −(i + j), for bi bj ∈ sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In  particular, �S2(H′  +) ⊂ sp+ (H′) acts on V by operators of negative degree,  hence �S2(H′  +) acts locally nilpotently on V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This implies that the action of  �S2(H′  +) on V ⊗C OS can be exponentiated, since the formula for the action  of exponentials of elements in �S2(H′  +) is locally a finite sum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Next, consider bi bj with i > 0 and j < 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' If i + j > 0, then the degree  of bi bj on V is still negative, hence bi bj acts locally nilpotently on V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' If  i + j < 0, then the degree of bi bj on V is positive;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' however, bi and bj com-  mute, and the degree of bi is negative, hence bi bj still acts locally nilpotently  on V , and thus this action can be exponentiated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Then, consider the case bi bj with i + j = 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Since V is Heisenberg–  admissible, the action of bi bj on V is diagonalizable with integral eigenvalues  by definition.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This action can be exponentiated to an action of the multi-  plicative group scheme Gm on V by letting a ∈ Gm act as multiplication by  ak on the eigenspace of bi bj with eigenvalue k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Finally, we discuss the case of an arbitrary element of sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  For  (Z, F, L) in �  Ag, Theorem 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2 implies that spF (H′) is preserved by the action  of sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' After quotienting by spF (H′), the Lie algebra sp+ (H′) factors  to �S2(H′  +)×  �  H′  + ⊗ Z/F  �  as in (3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1), thus the action of sp+ (H′) on V ⊗COS  factors to an action of �S2(H′  +)×  �  H′  + ⊗ Z/F  �  on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This implies that for  an arbitrary element of sp+ (H′), only finitely many terms bi bj with i+j ≤ 0  act locally non-trivially on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Using the arguments in the previous  paragraphs, one checks that the formula for the action of exponentials of  elements in sp+ (H′) with only finitely many terms bi bj with i + j ≤ 0 is  locally a finite sum on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The statement follows.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  26  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Sheaves of coinvariants on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Let V be a Heisenberg–admissible  vertex algebra.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From Proposition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, the sheaf �V(V ) on �  Ag carries an equi-  variant action of Sp+ (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, Sp+ (H′) acts transitively on  the fibers of the map �  Ag → Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It follows that the quotient of �V(V ) by the  action of Sp+ (H′) descends along the projection �  Ag → Ag to a sheaf on Ag,  which we call the sheaf of coinvariants V(V ) on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has a Cartesian  diagram  (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3)  �V(V )  V(V )  �  Ag  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Applying Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, we are now ready for:  Proof of Theorems 1 and 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, the sheaf �V(V ) on �  Ag car-  ries an action of the Atiyah algebra c  2 FΛ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Since this action is compatible  with the action of Sp+ (H′), it induces an action of the Atiyah algebra c  2 FΛ  on the sheaf V(V ) on Ag, hence the statements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  Example 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' When c = 0, the action of the Atiyah algebra factors to an  action of the tangent sheaf to Ag on the sheaf of coinvariants V(V ) on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Hence for c = 0, the sheaf V(V ) is more simply a D-module on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The action of Sp+ (H′) ⋉ O×  1 .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Next, we discuss how to construct  similarly sheaves of coinvariants on Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For this, we start describing the  action of Sp+ (H′) ⋉ O×  1 on the sheaf of coinvariants on �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Let V be a vertex operator algebra admitting an embedding π → V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From  Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2, the sheaf �V(V ) on �  Xg carries an action of the Atiyah algebra  −c FΘ, where c is the central charge of the embedding π → V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This is  induced by an action of �  U2(H) on �V(V ) via the projection �  U2(H) → −c FΛ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Composing with the inclusion (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2), we deduce an action of sp+ (H′) ⋉ H′  +  on the sheaf �V(V ) on �  Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proposition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex algebra V , the action  of sp+ (H′)⋉H′  + on the sheaf �V(V ) on �  Xg can be exponentiated to an action  of Sp+ (H′) ⋉ O×  1 on �V(V ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The statement follows similarly to Proposition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1, since elements in  Sp+ (H′) ⋉ O×  1 are products of exponentials of elements in sp+ (H′) ⋉ H′  +,  and H′  + acts locally nilpotently on V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Sheaves of coinvariants on Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a Heisenberg–admissible vertex  algebra V , Proposition 8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3 gives an equivariant action of Sp+ (H′) ⋉ O×  1  on the sheaf �V(V ) on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Since from Theorem 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3, Sp+ (H′) ⋉ O×  1 acts  transitively on the fibers of the map �  Xg → Xg, it follows that �V(V ) descends  along the projection �  Xg → Xg to a sheaf on Xg, which we call the sheaf of  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 27  coinvariants V(V ) on Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' One has a Cartesian diagram as in (8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3), with  �  Ag → Ag replaced by �  Xg → Xg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Proof of Theorems 3 and 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' From Theorem 7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2, the sheaf �V(V ) on �  Xg car-  ries an action of the Atiyah algebra −c FΘ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Since this action is compatible  with the action of Sp+ (H′)⋉O×  1 , it induces an action of the Atiyah algebra  −c FΘ on the sheaf V(V ) on Xg, hence the statements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  □  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Final remarks  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Geography of Harish-Chandra pairs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The constructions of the  sheaves of coinvariants in §8 are variations on the formalism of localization  of modules over Harish-Chandra pairs first introduced in [BB] and further  developed in [BFM, BS] and [FBZ, §17.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A Harish-Chandra pair (g, K)  consists of a Lie algebra g and a Lie group K verifying some compatibility  conditions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The localization functor assigns to a module over (g, K), i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='e.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=',  a vector space with compatible actions of g and K, a (possibly twisted)  D-module on a variety identified by the Harish-Chandra pair.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For instance,  localizations of: modules over (Der (O) , Aut (O)) (see notation from §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4)  yield D-modules on a smooth curve;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' modules over (Witt, Aut (O)) yield D-  modules on the moduli space Mg,1 of pointed smooth curves of genus g;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' and  modules over (Vir, Aut (O)) yield twisted D-modules on Mg,1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We refer to  [FBZ] for a discussion of these and more geometries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The construction of the twisted D-modules of coinvariants on Ag and Xg  in §8 can be interpreted as the result of the localization of modules over the  Harish-Chandra pairs  �  mp  �  H′�  , Sp+ �  H′��  and  �  �  U2(H), Sp+ �  H′�  ⋉ O×  1  �  ,  respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' We emphasize a difference here with respect to the geometry  of curves: While the group Aut (O) acts simply transitively on the fibers of  �  Mg → Mg,1, the group Sp+ (H′) acts transitively, but not simply, on the  fibers of �  Ag → Ag, as discussed in §3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Comparison with classical coinvariants on curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For a vertex  operator algebra V , the space of coinvariants at (C, P, t) ∈ �  Mg constructed  in [FBZ] is the quotient of V by the action of a Lie algebra LC\\P (V ) de-  pending on both V and the open subset C \\ P ⊂ C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The kernel of the map  Witt → T(C,P,t)( �  Mg) is a Lie subalgebra of LC\\P (V ), but in general is not  equal to it.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It is shown in [FBZ] how the construction globalizes over �  Mg  and yields an Aut (O)-equivariant twisted D-module on �  Mg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This thus de-  scends along the principal Aut (O)-bundle �  Mg → Mg,1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Furthermore, since  the resulting fibers at (C, P) and (C, Q) in Mg,1 are canonically isomorphic  for all P, Q ∈ C, the sheaf is constant along the fibers of Mg,1 → Mg and  thus descends to a twisted D-module on Mg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  28  N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' TARASCA  For a vertex operator algebra V admitting an embedding π → V , the  space of coinvariants at (Z, F, L) ∈ �  Ag from §7 is the quotient of V by the  action of the Lie algebra spF (H′).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Contrary to LC\\P(V ), the Lie algebra  spF (H′) is independent of V and equals the kernel of the analogous map  sp (H′) → T(Z,F,L)( �  Ag), hence it is the smallest Lie algebra whose coinvari-  ants yield twisted D-modules on �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' This implies that the push-forward via  the Torelli embedding Mg → Ag of the sheaf of coinvariants for LC\\P(V )  on Mg does not map to the sheaf of coinvariants for spF (H′) on Ag for a  general V .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' For this, it is natural to determine a Lie algebra containing as  Lie subalgebras both spF (H′) and LC\\P (V ) at points in the Jacobian locus.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  We will present such an extension in a follow-up work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  The spaces of coinvariants for LC\\P (V ) are known to have finite dimension  when V satisfies some finiteness and semisimplicity conditions [AN, DGT2],  and thus give rise to vector bundles of coinvariants on Mg whose Chern  classes are determined by their twisted D-module structure [DGT1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  It  would be interesting to determine a similar result on spaces of coinvariants  on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The mentioned extension of spF (H′) will provide a better context  for investigating this property, which we intend to explore accordingly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  9.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Failing descent for arbitrary modules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Spaces of coinvariants for  LC\\P(V ) have been constructed also for the action of LC\\P(V ) on an ar-  bitrary V -module [FBZ].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  These give rise to twisted D-modules on Mg,1  [DGT2, §8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7], which in general do not descend on Mg.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In fact, the descent  along Mg,1 → Mg is only possible after tensoring the sheaf of coinvariants  by an appropriate power of the relative cotangent line bundle to offset the  variation of the spaces of coinvariants along the fibers of Mg,1 → Mg (as  in [DGT2, §8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='7]).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Similarly, the twisted D-modules of coinvariants from  arbitrary V -modules constructed in §7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4 in general do not descend on Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  As the relative H2-space for the map �  Ag → Ag is trivial (Proposition 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='4),  tensoring by a line bundle will not help here.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' It would be interesting to find  a finite-dimensional extension of the moduli space Ag where the sheaves of  coinvariants from arbitrary modules could descend from �  Ag.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  References  [ADC]  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Arbarello and C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' De Concini.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Abelian varieties, infinite dimensional Lie alge-  bras, and the heat equation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In Proceedings of Symposia in Pure Mathematics,  volume 53, 1991.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑1, ↑2, ↑3, ↑8, ↑9, ↑10, ↑11, ↑12, ↑13, ↑14, ↑16  [ADCK]  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Arbarello, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' De Concini, and V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Kac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The infinite wedge representation and  the reciprocity law for algebraic curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In Theta functions—Bowdoin, volume  49, Part 1, pages 171–190.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' American Mathematical Society, 1987.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑3, ↑4  [ADCKP] E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Arbarello, C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' De Concini, V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Kac, and C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Procesi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Moduli spaces of  curves and representation theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Comm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', 117(1):1–36, 1988.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑3,  ↑10, ↑12, ↑13, ↑14, ↑16, ↑17, ↑19, ↑20  [AN]  T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Abe and K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Nagatomo.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Finiteness of conformal blocks over compact Rie-  mann surfaces.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Osaka J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', 40(2):375–391, 2003.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑28  COINVARIANTS OF VERTEX ALGEBRAS ON MODULI OF ABELIAN VARIETIES 29  [BB]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Beilinson, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' and J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Bernstein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A proof of Jantzen conjectures.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Gelfand Seminar, volume 16 of Adv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Soviet Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', pages 1–50.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Amer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', Providence, RI, 1993.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑27  [BD]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Beilinson and V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Drinfeld.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Quantization of Hitchin’s integrable system  and Hecke eigensheaves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Preprint, available at http://math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='uchicago.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='edu/ drin-  feld/langlands/QuantizationHitchin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='pdf, 1991.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑3, ↑14, ↑15  [BFM]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Beilinson, B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Feigin, and B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Mazur.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Introduction to algebraic field theory  on curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Unpublished, 1991.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑27  [BS]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Beilinson and V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Schechtman.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Determinant bundles and Virasoro  algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Comm.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', 118(4):651–701, 1988.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑2, ↑27  [BZN]  D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Ben-Zvi and T.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Nevins.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' W-symmetry of the ad`elic Grassmannian.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Commu-  nications in Mathematical Physics, 293(1):185–204, 2010.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑1  [DGT1]  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Damiolini, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Gibney, and N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Tarasca.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Conformal blocks from vertex alge-  bras and their connections on Mg,n.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Geometry & Topology, 25(5):2235–2286,  2021.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑28  [DGT2]  C.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Damiolini, A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Gibney, and N.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Tarasca.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' On factorization and vector bundles of  conformal blocks from vertex algebras.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Annales Scientifiques de l’ ´Ecole Normale  Sup´erieure, to appear, arXiv:1909.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='04683, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑28  [FBZ]  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Frenkel and D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Ben-Zvi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Vertex algebras and algebraic curves, volume 88  of Mathematical Surveys and Monographs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Am Mathem Soc, Providence, RI,  second edition, 2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑1, ↑3, ↑6, ↑7, ↑12, ↑14, ↑15, ↑27, ↑28  [FHL]  I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Frenkel, Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='-Z.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Huang, and J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Lepowsky.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' On axiomatic approaches to ver-  tex operator algebras and modules.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Mem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Amer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Soc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', 104(494):viii+64,  1993.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑21, ↑24  [FP]  R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Fringuelli and R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Pirisi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The Picard group of the universal abelian variety  and the Franchetta conjecture for abelian varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Michigan Mathematical  Journal, 68(3):651–671, 2019.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑12  [FS]  E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Frenkel and M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Szczesny.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Twisted modules over vertex algebras on algebraic  curves.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Advances in Mathematics, 187(1):195–227, 2004.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑1  [Hai]  R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Hain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Moduli of Riemann surfaces, transcendental aspects.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In School on  Algebraic Geometry (Trieste, 1999), pages 293–353.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Abdus Salam Int.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Cent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Theoret.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Phys.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', Trieste.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑12  [Kac]  V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Kac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Vertex algebras for beginners, volume 10 of University Lecture Series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='  Am Mathem Soc, Providence, RI, 1997.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑21  [TUY]  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Tsuchiya, K.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Ueno, and Y.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Yamada.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Conformal field theory on universal  family of stable curves with gauge symmetries.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In Integrable systems in quantum  field theory and statistical mechanics, volume 19 of Adv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Stud.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Pure Math.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=',  pages 459–566.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Academic Press, Boston, MA, 1989.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑1  [VDG]  G.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' Van Der Geer.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' The cohomology of the moduli space of abelian varieties.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' In  Handbook of Moduli I, volume 24 of Advanced Lectures in Mathematics, pages  415–458.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' International Press of Boston, Inc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=', 2013.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content=' ↑12  Nicola Tarasca  Department of Mathematics & Applied Mathematics  Virginia Commonwealth University, Richmond, VA 23284  Email address: tarascan@vcu.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
+page_content='edu' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/ytFQT4oBgHgl3EQfBjWV/content/2301.13227v1.pdf'}
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+View fusion vis-`a-vis a Bayesian interpretation of Black-Litterman
+for portfolio allocation.
+Trent Spears*†, Stefan Zohren∗, Stephen Roberts∗
+February 1, 2023
+Summary
+The Black-Litterman model extends the framework of the Markowitz Modern Portfolio Theory to in-
+corporate investor views. We consider a case where multiple view estimates, including uncertainties,
+are given for the same underlying subset of assets at a point in time. This motivates our consideration
+of data fusion techniques for combining information from multiple sources. In particular, we consider
+consistency-based methods that yield fused view and uncertainty pairs; such methods are not common to
+the quantitative finance literature. We show a relevant, modern case of incorporating machine learning
+model-derived view and uncertainty estimates, and the impact on portfolio allocation, with an example
+subsuming Arbitrage Pricing Theory. Hence we show the value of the Black-Litterman model in combi-
+nation with information fusion and artificial intelligence-grounded prediction methods.
+Keywords: Black-Litterman portfolio allocation, information fusion, machine learning, financial time-
+series analysis.
+1
+Introduction
+The Black-Litterman model extends the Markowitz portfolio optimisation framework to incorporate investor
+beliefs about asset returns [1]. Such beliefs are termed ‘views’. In its original formulation, the Black-
+Litterman framework is such that a given view induces an update of a prior assumption about the mean
+parameter of a Gaussian return distribution. Making use of views in this way can result in non-trivial
+differences to the estimated weights of a portfolio allocation strategy, and hence the relative investment
+outcome.
+Views can be obtained from diverse sources, including market pundit opinions, Reserve Bank statements,
+and as output of statistical models. Consequently, in practice, a portfolio manager or trader may possess
+multiple views about the same underlying asset, or subset of assets, over the next investment period. A
+contribution of this work is to both consider and extend the Black-Litterman framework to incorporate
+multiple such views.
+It is natural to formalise elements of the Black-Litterman model with respect to ideas from Bayesian statis-
+tics. See [2] for a review summary, with [3, 4] intriguing supplements. We note that the modelling of this
+paper presupposes the canonical Bayes-based Black-Litterman formalism. This approach is useful for prac-
+titioners in allowing for a strong theoretical grounding of the model prior in the Capital Asset Pricing Model
+(CAPM) [5], and for the relative ease with which one can incorporate market views. Specifically, views are
+*University of Oxford, Oxford-Man Institute of Quantitative Finance.
+†Corresponding author. E-mail: trent@robots.ox.ac.uk
+1
+arXiv:2301.13594v1  [q-fin.PM]  31 Jan 2023
+
+given as a function of asset mean return estimates, and accompanied by an uncertainty estimate that encap-
+sulates a notion of confidence about that mean. The specification of the view uncertainty is a domain for
+debate in the literature. In contrast, the uncertainty specification is of critical importance to the mechanics
+of the Bayesian estimation framework. The literature often tacitly assumes that uncertainty is to be specified
+in excess of the given mean estimate. A prevailing method is to set the uncertainty term in proportion to a
+quantity such as an estimate of the underlying return covariance. The proportionality constant can then be
+tuned akin to a model hyperparameter. Such ad hoc specification can be unsatisfying; fortunately, scientific
+modelling offers an alternative.
+Machine learning methods are enjoying a resurgence as oracles for financial markets, particularly given the
+advances underlying modern deep learning. Indeed, such methods have utility for forecasting time-series,
+and predictions are often naturally partnered with uncertainty estimates. Such uncertainties are typically
+categorised in the literature as aleatoric or epistemic. Aleatoric uncertainty relates to the modelled ran-
+dom error of the underlying data generating process, while epistemic uncertainty encompasses much more,
+including error relating to the model specification, which also subsumes uncertainties about parameter esti-
+mates. These two categories of uncertainty are recognised across multiple research domains, and the models
+contained therein. In any case, the estimation of views by statistical forecasting models, coupled with the
+uncertainty estimate, allows for a more principled approach to setting view parameters when modelling with
+Black-Litterman. We describe this further in Section 3 below. This interpretation stands in stark contrast to
+existing methods – with one popular technique described above – that are more ad hoc. Our approach has
+the further benefits of preserving the intent of the canonical model, and has utility for automating an aspect
+of the investment decision-making process.
+Further our extended modelling framework, we consider combining multiple views for expected returns
+over the next time increment with respect to view correlation that may be non-zero. Although we con-
+sider the single-step case, we are inspired by the relationship between Black-Litterman and a state-space
+modelling framework as recently described in [6]. Indeed, at the core of our approach are techniques from
+the information fusion literature, that allow us to combine views in a principled way. In Section 3, we
+present methods for fusing views assuming both zero and non-zero correlation between them, and consider
+a conservative fusion method for sets of views that may be inconsistent with one other (according to some
+distance metric between distributions). In their relative simplicity, the principles of these fusion methods
+are understandable, and the resulting fused estimate are explainable. Some practitioners may find this ad-
+vantageous relative to alternative black box methods. In our empirical work, we find fusion-based methods
+that improve on of the mean and median of our 3 view-generating models in a statistically meaningful way.
+This is interesting to the investment practitioner that cannot know ex-ante which of a set of views might
+outperform; a fusion-based method may be selected instead.
+To show the utility of data fusion, and in connection with recent work by [4], we offer an application of the
+Black-Litterman model assuming a multi-factor model for asset returns. Factor models present in finance
+with various specifications; see [7] for a recent review. We consider a conditional factor model, as inspired
+by the Arbitrage Pricing Theory (APT) of Ross [8]. In Section 2, before we further develop view fusion in
+Section 3, we expound on the Black-Litterman-APT as a Bayesian hierarchical model; a schematic for the
+model is given in Figure 1 below. In Section 2.3 we carefully derive the solution for the optimal portfolio
+weights under an unconstrained Markowitz portfolio allocation as a further contribution to the literature.
+With a desire to extend our empirical work, we offer a preliminary model accounting for transaction costs,
+with details specified in Section 2.4 This model permits a reasonable proof-of-concept, that could be built
+upon for industrial application or as future academic work.
+Notes for the data set construction are offered in Section 4. To the extent the raw data is available in the
+2
+
+Figure 1: LHS: Schematic of the Black-Litterman methodology as it applies to the APT model. Asset returns
+are linearly projected onto factor returns, and the algorithm at the level of the factor model is such that at
+each time-step views are collected, before the factor returns model is updated and predictions gleaned. RHS:
+Hierarchical schematic suggestive of the relationship between terms in the BL-APT model, as described in
+Section 2.
+public domain (via the Wharton Research Data Service), these notes could lead to a straightforward repli-
+cation. In Section 5, we use the ideas and results of the preceding sections to give empirical results that
+showcase view fusion whereby estimates – including measures of uncertainty – are sourced from a collec-
+tion of machine learning models. We discuss the ways in which fusion-based methods lead to investment
+outperformance relative to methods based on a singular view. We also constrast our methods with the dif-
+ficult benchmark of a buy-and-hold investment in the S&P 500. We conclude and summarise avenues for
+future work in Section 6.
+2
+Black-Litterman
+2.1
+A recap
+Assume there exist n investable assets within a market with excess return vector r whose distribution is
+modelled as multivariate normal over discrete time increments, denoted r ∼ MVN(µ, Σ). Here µ denotes
+the mean vector of returns, and Σ denotes the return covariance. Then in a Markowitz Modern Portfolio
+Theory framework [9], assuming a single-period investment setting, the investor portfolio weights w =
+(w1, ..., wn) are a solution to the mean-variance optimisation problem:
+max
+w∈C
+E(w′r) − γ
+2var(w′r).
+(1)
+Here C is a set of weight constraints, if any, and γ > 0 is the investor risk aversion parameter, denoting
+preferences balancing return and risk. In the unconstrained case, differentiating eq. (1), setting it to 0 and
+3
+
+Factor returns
+qQ
+sv
+Collect
+view
+Update
+F
+μf
+model
+D
+Predict
+f
+X
+Asset returns
+Induces return
+distribution
+estimate and
+r
+portfolio
+allocationsolving for the optimal portfolio weights w∗ in terms of (µ, Σ) yields
+w∗ = (γΣ)−1µ.
+(2)
+On analysing the second derivative one finds that this solution is indeed a maximum. In practice, these
+weights could be solved for – and a portfolio subsequently implemented – upon estimation of the return
+distribution parameters, for example, upon substitution of a computed sample mean vector and sample
+covariance matrix, given historical data.
+The Black-Litterman model [1] extends this framework to incorporate (subjective) investor beliefs about
+asset returns, that are called ‘views’. A single view is assumed to be a function of real-valued vectors
+of length n denoting portfolio weights p and expected asset returns µ, a real-valued scalar denoting the
+portfolio value q, and a strictly positive real-valued scalar ϵ denoting uncertainty in the portfolio value, that
+can be written
+p′µ = q + ϵ.
+(3)
+To be explicit, let us call a collection of k views a ‘range’, for natural numbers k. Then similar to the original
+presentation of Black and Litterman, a range of views can be arranged thus:
+P µ = q + ϵ,
+ϵ ∼ N(0, Ω).
+(4)
+Here P ∈ Rk×n is a real-valued matrix of portfolio weights, where the kth row is given by p′
+k as defined
+above; q ∈ Rk is a real-valued vector collecting k portfolio values; and Ω ∈ Rk×k is assumed to be a
+diagonal matrix of portfolio value estimate uncertainties, where we have further assumed independence
+between views.
+Given the above formulation, a view can express both ‘absolute’ and ‘relative’ relationships between mean
+asset returns. The case of an absolute (normalised) view corresponds to p taking a unit value at the ith
+entry, and zero otherwise, so that the left-hand side of eq. (3) equals µi. Any other (non-trival) view we call
+relative; a common relative view, for example, is a belief on the return spread µi − µj = q. This could be
+expressed by setting alternate positive and negative unit values at the i and j index of p, and zero elsewhere.
+In the work that follows, we assume absolute views. We further assume that P is of full rank.
+Given these preliminaries, the Black-Litterman model is such that the existing return distribution parameter
+assumption is updated given views. We understand such updating in the context of Bayesian statistics, as
+prior authors have noted [2–4, 6].
+The Bayesian specification assumes a prior distribution p(θ), where θ denotes the target parameter of the
+return distribution that we wish to express via a parametric probabilistic model. Most commonly, θ = µ.
+The original authors – and many since – set the prior given an estimate of the CAPM model [5], and hence
+underwriting the prior with a foundational theoretical result.
+Next, the view is related to the target parameter via a likelihood function p(q|θ), such that, by the laws of
+conditional probability and Bayes’ Theorem, an updated posterior distribution for the target parameter is
+given by
+p(θ|q) ∝ p(q|θ)p(θ).
+(5)
+Finally, we can write a posterior predictive distribution for the asset returns given the views as
+p(r|q) =
+�
+p(r|θ)p(θ|q)dθ.
+(6)
+Hence, the expectation and covariance of the random quantity r|q can be computed analytically – or other-
+wise estimated if the integral is intractable – before substitution into, say, eq. (2) to yield a solution to the
+portfolio allocation problem.
+4
+
+2.2
+Black-Litterman in the context of Factor models
+In line with recent work by [4], we offer an application of the Black-Litterman model assuming a factor
+model for asset returns, and we conveniently conform with some of their notation.
+For context, we note that in many investment studies of equity markets the empirical estimation of the return
+covariance is challenging, especially when the universe of equities under consideration is large. The linear
+factor model that we outline below, whereby k ≪ n, is relatively practical and efficient. This has contributed
+to its popularity within the literature, and bolsters the case for industrial use [10]. We consider a conditional
+factor model, as inspired by the Arbitrage Pricing Theory (APT) of Ross [8]. In the single-period investment
+setting, we model
+r = Xf + ϵr,
+ϵr ∼ N(0, D).
+(7)
+Here r is the n-dimensional random vector containing the cross-section of excess returns for n equities over
+the next time increment [t, t+1]; X is a non-random n×k matrix of observable factor exposures estimated
+at t, for k the number of explanatory asset factors; D is a covariance matrix for the returns, also known at t
+and assumed to be diagonal; and f is a k-dimensional latent factor vector that we estimate at each time step
+by cross-sectional regression. Within a Black-Litterman framework, consider that our parameter of interest
+is now θ = µf, such that
+f = µf + ϵf,
+ϵf ∼ N(0, F ).
+(8)
+We refer to the elements of µf as the factor risk premia.
+Black-Litterman in the context of APT, henceforth labelled ‘BL-APT’, amounts to a Bayesian hierarchical
+model. A schematic for the model is given in the right-hand panel of Figure 1. We note that in comparison
+to the Black-Litterman model applied to the return mean, an analogue to the CAPM prior does not exist.
+In the work that follows, we set the prior parameters as a simple function of recent data, per the discussion
+in Section 5. On the other hand, view estimates for the factor risk premia at time t induce return forecasts
+(with uncertainties) over the next time period. These parameter estimates can then be utilised to estimate
+portfolio weights.
+In the next section, we carefully show the derivation for the optimal portfolio weights of an unconstrained
+‘BL-APT’ as a reference contribution to the literature.
+2.3
+Solving for optimal weights – Hierarchical Bayesian Black-Litterman for APT
+We can express our model for asset returns, factor returns and views carefully as a hierarchical Bayesian
+model, with a suggestive schematic shown in Figure 1 above. We derive the optimal portfolio allocation
+after finding p(r|q), as defined below.
+We begin by writing the joint distribution of random variables of interest as a conditional probability:
+p(r, f, θ, q) = p(r, f|θ, q)p(θ, q).
+Substituting p(θ, q) = p(θ|q)p(q) and dividing both sides by p(q) yields
+p(r, f, θ|q) = p(r, f|θ, q)p(θ|q).
+Integrating both sides over θ we find that
+p(r, f|q) =
+�
+p(r, f|θ, q)
+�
+��
+�
+=p(r,f|θ)
+p(θ|q)dθ.
+5
+
+Again integrating both sides, this time with respect to f, we have that
+p(r|q) =
+��
+p(r, f|θ)p(θ|q)dθdf.
+(9)
+With one more simplification, writing p(r, f|θ) = p(r|f, θ)p(f|θ) = p(r|f)p(f|θ), we find
+p(r|q) =
+�
+p(r|f)
+�
+p(f|θ)p(θ|q)dθ
+�
+��
+�
+=p(f|q)
+df.
+(10)
+Since we assume θ = µf, there holds the well-known facts that the posterior p(θ|q) is normal and that the
+posterior predictive p(f|q) is normal. Hence it is clear that p(r|q) is also normal, with its expectation and
+covariance given in closed-form by the following three-step process.
+Firstly, choosing the prior p(θ) ∼ N(ξ, V ), by Bayes’ rule for linear Gaussian systems, as in [11], we have
+that the posterior p(θ|q) is multivariate normal with covariance and mean
+var(θ|q) = (V −1 + Ω−1)−1,
+E(θ|q) = var(θ|q) · (V −1ξ + Ω−1q).
+Secondly, recall the convolution integral for sums of random variables: if Xi
+i.i.d.
+∼ N(µi, Σi), i = 1, 2, then
+f(z) :=
+�
+fX1(x)fX2(z − x)dx ∼ N(µ1 + µ2, Σ1 + Σ2).
+(11)
+Writing the inner integral of eq. (10) with the change of variable f �→ f − θ, we find
+p(f|q) =
+�
+p(f − θ|θ)
+�
+��
+�
+∼N(0,F )
+p(θ|q)dθ
+so that by eq. (11) we have that p(f|q) is normally distributed with expectation and covariance given by
+E(f|q) = (V −1 + Ω−1)−1 · (V −1ξ + Ω−1q) = E(θ|q),
+var(f|q) = (V −1 + Ω−1)−1 + F = var(θ|q) + F .
+Thirdly, we solve the outer integral of eq. (10) (deferring some of the details of the algebraic manipulations
+to the Appendix, for brevity). Writing
+p(r|q) =
+�
+p(r|f)p(f|q)df,
+(12)
+we collect and expand the terms in the exponent up to a factor of − 1
+2, complete the square in f, and integrate
+what is recognisable as a Gaussian integral. By the recursive nature of the integrals, it is clear that we also
+retrieve a Gaussian for r|q. Hence, as supported by further calculations within the Appendix below, we
+have that the posterior predictive distribution p(r|q) is multivariate normal with covariance and mean
+var(r|q) =
+�
+D−1 − D−1X
+�
+XT D−1X + var(f|q)−1�−1XT D−1�−1,
+E(r|q) = var(r|q)D−1X
+�
+XT D−1X + var(f|q)−1�−1var(f|q)−1E(f|q).
+By eq. (2), we write the optimal weights for a single-step Black-Litterman portfolio allocation as
+h∗
+blb = γ−1var(r|q)−1E(r|q)
+= γ−1D−1X
+�
+XT D−1X + var(f|q)−1�−1var(f|q)−1E(f|q).
+(13)
+This expression differs meaningfully with other optimal weights given in the literature. This is the case in
+that we have carefully accounted for all of the specified terms within the hierarchy of the returns model.
+6
+
+2.4
+An optimal weight model under transaction costs
+In this section we consider a more realistic objective function for solving for portfolio weights, in that it
+incorporates transaction costs. We do this by making a minimal adjustment to the Markowitz objective of
+eq. (1):
+max
+w∈C
+E(w′r) − γ
+2var(w′r) − TC,
+(14)
+with TC denoting transaction costs measured in percentage of invested wealth. Of the many ways to account
+for transaction costs, we broadly follow the single-period model recently presented in [12]. Despite the
+differences in our application domains, our analysis and results contrast somewhat consistently, and certainly
+interestingly, with theirs.
+Firstly, we choose a transaction cost model inspired by [13] so that transaction costs measured in dollars,
+TCd, is given by
+TCd
+t = 1
+2∆′
+tΛt∆t.
+Here ∆t is the portfolio turnover vector for a time increment, defined as
+∆t := Πt(wt − Rt−1wt−1),
+and the ‘market impact’ vector m is given by
+mt = 1
+2Λt∆t.
+We use the subscript t to explicitly account for time-dependence. The real scalar Πt denotes total wealth
+investable at time t. Clearly, given the above specification dollar transaction-costs erode dollar returns
+quadratically with increasing wealth. The term Rt−1 denotes a diagonal matrix whose diagonal elements
+account for the realized returns for the assets held in the portfolio at t − 1, over the time step [t − 1, t), and
+adjusted for wealth delta. We assume that the term Λt is a diagonal matrix whose elements depend on the
+daily (dollar) volume traded in each underlying asset. Given the recent estimates of [14], we assume a 10
+basis point market impact when trading 1% of the daily dollar volume Lt of US equity underlyings whether
+long or short, so
+mt = 10bps · 1 = 1
+2Λt × 1%Lt
+=⇒ Λt = 1
+5L−1
+t .
+(15)
+In the work that follows, we set the values for daily dollar volumes at their 6 month rolling average. Further,
+we assume that investor wealth grows proportionally with the market; specifically, we make the somewhat
+arbitrary assumption that at each time step the total investable capital is one-tenth of the sum of the daily
+dollar volumes of the assets in our trade universe, as known at the most recent time step.
+Hence eq. (14) can be written, noting that TC = TCd/Π, as
+max
+wt∈C
+E
+�
+w′
+trt
+�
+− γ
+2var
+�
+w′
+trt
+�
+− Πt
+2
+�
+wt − Rt−1w∗
+t−1
+�′Λt
+�
+wt − Rt−1w∗
+t−1
+�
+(16)
+and conveniently solved in closed-form for optimal weights:
+w∗
+t =
+�
+γΣt + ΠtΛt
+�−1�
+µt + ΠtΛtRt−1w∗
+t−1
+�
+.
+(17)
+Hence the optimal portfolio weights for the BL-APT model can be found by substituting estimates for
+E(r|q) and var(r|q) into eq. (17), as an alternative to eq. (13), when taking transaction costs into account.
+7
+
+3
+View fusion
+3.1
+Preliminaries
+The Black-Litterman model – sans solving for the portfolio weights – can be expressed via a state-space
+representation; this was recently presented in [6] in the context of modelling temporal dependency in asset
+returns and parameter view estimates1. In a simple case, consider ranges of views generated from a source
+at discrete time increments k = 0, 1, ... . We can infer the underlying target mean µk in an online way, via
+the linear time-varying system of equations:
+µk+1 = µk + ϵµ
+k ,
+(18)
+qk = Pkµk + ϵq
+k.
+(19)
+Here ϵµ
+k and ϵq
+k model independent zero-mean white-noise processes with respective covariances Ψk and
+Σk. We call equations (18) and (19) the ‘state’ and ‘measurement’ equations, respectively. Solving the state-
+space representation of Black-Litterman, assuming absolute views, we have the probability distribution for
+µk|qk, analogous to eq. (5) and solved equivalently to solving for p(θ|q) per Section 2.1. The predictive
+distribution for µk+1|qk, analogous to eq. (6) can be solved equivalently to solving for p(f|q), also of
+Section 2.1. On the other hand, within the Black-Litterman literature, as in our model from Section 2,
+the prior is typically re-initialised to p(µ0) at each time-step, rather than dynamically updated given a
+sequence of view estimates. In the following work, we follow this approach, and leave consideration of
+prior updates based on a larger subset of recent data as future work. In any case, such state-space modelling
+naturally inspires an extension of the Black-Litterman framework to handle the combination – or ‘fusion’ –
+of multiple views held about a particular portfolio.
+3.2
+Information fusion
+To this point we have described the Black-Litterman model assuming a singular source for a range of views.
+Next, we consider the realistic – though in the context of Black-Litterman modelling, unexplored – case of
+multiple sources generating views simultaneously for each time increment, and analyse the impact on the
+predictive distribution. We extend eq. (19) thus (for brevity, keeping to the case of absolute views):
+qk,s = µk,s + ϵ(q)
+k,s,
+(20)
+where qk,s denotes the view is from source s, 1 ≤ s ≤ S, and each ϵ(q)
+k,s is a zero-mean white-noise process
+with covariance Σk,s. Multiple views could realistically arise in the context of implementing a systematic
+trading or asset management strategy, whereby multiple predictions across multiple (potentially, broadly
+diverse) models need to be fused before capital allocation.
+Information fusion has been common to the state-space literature since the work of [16]. However, fusion
+is not limited to the state-space framework, and instead applies more generally to the problem of fusing
+multiple estimates of an underlying random variable2. Correspondingly, data fusion can take place at the
+level of the state or measurement equations, though we assume the former for our empirical work below.
+Typically, fusion techniques amount to solving for an optimal fused estimate (�µ, �Σ) for the true underlying
+values (µ, Σ) given a collection of S underlying estimates {(�µs, �Σs) : 1 ≤ s ≤ S}, with the mean
+1There exists an extensive literature on state-space modelling, with applications across many domains. See, for example, [15] for
+an instructive review of filtering methods for mathematical finance.
+2Various approaches exist in the data fusion literature for incorporating information from multiple sources; introductory reviews
+can be found in [17, 18].
+8
+
+Figure 2: Concentration ellipses for three example bivariate Gaussian measurements of a single state x =
+(x1, x2) (light orange), and the optimal fused state estimates for the four methods outlined in Section 3.
+parameter a weighted linear combination of the underlying estimates:
+�µ =
+�
+s
+Ws �µs.
+(21)
+[We have omitted the subscript k, for ease of notation.] ‘Optimal’ fusion is such that (i) �Σ is minimal
+in some sense – typically with respect to matrix trace or determinant; and also that (ii) �Σ is consistent.
+Within the fusion literature, a consistent estimate is such that �Σ ≥ Σ, in the sense that �Σ − Σ is positive
+semi-definite. That is, the consistent estimate subsumes a covariance no less than the covariance Σ of the
+distribution of the true underlying process; see, for example, [19]. We note that this definition is independent
+of the well-known definition of a consistent estimator from the statistical literature, whereby a parameter is
+called consistent if it converges in probability to the true value of the parameter. The consistency property is
+crucial for many investors conscious of risk, in particular those that do not want to understate risk3. Another
+benefit of consistency is that probabilistic bounds for the state of the system can be deduced, as discussed in
+[21].
+Given the mean and covariance of a bivariate random variable, recall the ‘concentration ellipse’ [22] defined
+as the locus of points {x : (x − µ)T Σ−1(x − µ) = 1}. For visual intuition, we depict such ellipses,
+estimated using the fusion methods described in the following subsections, in Figure 2 above. These results
+are shown for the case of three underlying data sources, assumed to each yield a noisy estimate of the same
+target.
+3In the case of (multi-period) Kelly investing, to which the fusion of this paper could directly apply, investment size is inversely
+proportional to variance. But the investor faces almost sure ruin if they sufficiently over-invest (which can happen if uncertainty is
+estimated to be too small) relative to the optimum strategy [20].
+9
+
+PW
+CI
+2 
+ICI
+CU
+1
+x2
++
+0
+-1 
+-1
+0
+1
+2
+3
+x13.2.1
+Precision-weighted fusion
+We first consider precision-weighted (PW) fusion for the case that the cross-covariances between sources is
+known to be 0. Suppose that for each s, �µs is an unbiased estimate, and each �Σs is a known error covariance
+estimate that is consistent. It follows that the fused estimate given in eq. (21) is an unbiased estimate if and
+only if �
+s Ws = I, for weight matrices Ws, and I the identity matrix. To find the weight estimates we
+solve
+min
+W
+trace(�Σ) subject to
+�
+s
+Ws = I.
+Let �Σij denote the cross-covariance estimate between the unique sources si and sj, and write
+�Σ =
+�
+s
+Ws �ΣsW T
+s +
+�
+si̸=sj
+Wsi �ΣijW T
+sj.
+(22)
+Assuming the cross-covariances are everywhere 0, solving for the optimal weights one finds that, on weight
+substitution,
+�Σ = (�Σ−1
+1
++ ... + �Σ−1
+S )−1,
+(23)
+�µ = �Σ(�Σ−1
+1 �µ1 + ... + �Σ−1
+S �µS).
+(24)
+Further details of this well-known result can be found in [16, 23]. The analogous result for fusing two
+sources that have known, non-zero correlation is given in [24], though for our financial modelling framework
+this is less useful since the cross-correlations are not estimated. On the other hand, the case of unknown,
+potentially non-zero cross-correlation is the domain of the Covariance Intersection method, as presented in
+the following subsection.
+3.2.2
+Covariance Intersection
+One could reasonably expect that views on the same underlying asset returns, as functions of similar or
+equal underlying data, exhibit non-zero cross-correlation. However, the cross-correlation is not necessarily
+known, or easily estimable. Such a setting is the domain of application for the Covariance Intersection (CI)
+fusion method of [25]. The insight of this approach is that, given eq. (22), the covariance ellipses for {�Σs}
+contain �Σ in their intersection, for any values of the cross-covariance terms. Hence the method yields
+�Σ−1 =
+�
+s
+ωs �Σ−1
+s ,
+(25)
+�µ = �Σ
+�
+s
+ωs �Σ−1
+s �µs,
+(26)
+for scalars ωs ∈ [0, 1] with �
+s ωs = 1, since a convex combination of covariances ensures �Σ encloses the
+intersection region. The ωs terms can be computed via a standard optimization routine subject to minimising
+the trace of �Σ. Further, it has been shown that the CI method applied to a pair of consistent estimates yields
+a consistent estimate [19]. Finally, equations (25) and (26) as given above extend the canonical case of two
+sources, as offered in [26].
+CI is a straightforward method that holds for any cross-covariance, but a cost of its flexibility is that the esti-
+mate can be too conservative for many practical use cases. We next consider Inverse Covariance Intersection
+that attempts to retain the consistency benefit of CI, while being less conservative.
+10
+
+3.2.3
+Inverse Covariance Intersection
+The method of inverse Covariance Intersection (ICI) is similar in approach to that of CI, but achieves a less
+conservative estimate while still maintaining consistency. The algorithm was presented recently in [27]. A
+central insight, inspired by [28], is to first consider estimates pairwise, such that for s = 1, 2:
+�µs = �Σs
+�
+(�Σs)−1 �µs + Γ−1γ
+�
+,
+(27)
+�Σs =
+�
+(�Σs)−1 + Γ−1�−1
+.
+(28)
+This is to say, that each estimate is itself the PW fusion of a sub-estimate from the collection {(�µs, �Σs) :
+1 ≤ s ≤ 2}, for sub-estimates uncorrelated between sources, and a shared set of information denoted
+(γ, Γ), also uncorrelated with each sub-estimate; we proceed assuming such a decomposition exist. If the
+shared information is known, then fusion can be solved optimally by subtracting the shared covariance from
+the PW fusion covariance for the original pair of estimates [27]. But since it is not known, the second
+insight is to instead solve for, and subtract, an upper bound for the shared covariance, valid for any true
+underlying shared information. Further, regardless of the shared information, it is shown that a consistent,
+tight covariance estimate – if it exists – is of the form
+�Σ−1 =
+2
+�
+i=1
+�Σ−1
+s
+−
+�
+2
+�
+s=1
+ωs �Σs
+�−1
+,
+(29)
+for scalars ωs as in the case of CI, with the ICI covariance estimate achieving this form exactly [27]. With a
+modicum of algebra, it follows that the fused mean is given by
+�µ =
+2
+�
+s=1
+Cs �µs,
+(30)
+where Cs = �Σ ·
+�
+�Σ−1
+s
+− ωs
+�
+2
+�
+s=1
+ωs �Σs
+�−1�
+.
+It is important to regonise that this formula does not generalise to more than two information sources in an
+obvious way – the ICI algorithm fuses information sources pairwise. However, ICI can be applied recur-
+sively. This follows from the assumption that any pairwise-fused estimate has a decomposition analogous
+to equations (27) and (28) [27]. For further results and details we also recommend [29].
+3.2.4
+Covariance Union
+The fusion methods outlined above assume that each source’s estimate is itself consistent with respect to
+the target. We relax this assumption by requiring that at least one of the source estimates is consistent. A
+given estimate could be inconsistent, as evidenced by, say, mean components sufficiently different between
+estimates, given relatively smaller covariance estimates. This could be apparent, for example, when the
+Mahalanobis distance between some pair of estimates exceeds a critical threshold. Further, we may not
+know precisely which of the underlying estimates is consistent, or it may be (in some sense) costly to
+resolve. The Covariance Union (CU) algorithm has been proposed as a fusion method for this setting [30].
+CU constructs a fused estimate guaranteed to be consistent, since the fused estimate is consistent with
+respect to each underlying estimate:
+�Σ ≥ �Σs + (�µ − �µs)(�µ − �µs)T ,
+1 ≤ s ≤ S.
+11
+
+Figure 3: Cumulative factor returns to risk premia as described in Section 2.2; replication of Figure 1 of [4].
+A single year is shown for ease of visualisation. The year 2011 is arbitrarily chosen.
+While the idea behind CU is relatively simple, the numerical implementation for estimating the fused esti-
+mate is more challenging. In an attempt to simplify the computation, we offer the following details. Firstly,
+CU can be implemented using non-convex optimisation software such as SolvOpt [31]. We follow [32] for
+implementing a SolvOpt-based solution for calculating the results of Section 5 below. Secondly, a key step
+is to define the coefficient vector that we wish to solve for, x. The first n elements of x are the elements of
+�µ, and the remaining n(n+1)
+2
+elements of x are the elements of the upper triangle of �Σ. Then x becomes the
+optimization target for SolvOpt. We seek to minimise the determinant of �Σ subject to the constraint that
+∀s,
+�Σ∗
+s := �Σ − �Σs − (�µ − �µs)(�µ − �µs)T ≥ 0.
+(31)
+A particular feature of the SolvOpt software is that it requires a constraint c(x) such that, for any input,
+c(x) ≤ 0. Since �Σ∗
+s is required to be positive semi-definite, it must have non-negative eigenvalues for all
+choices of s, and the constraint is satisfied for a choice of c such that
+−c(x) := min{{eigenvalues(�Σ∗
+s) : ∀s}} ≥ 0.
+Finally, for the interested reader, the works of [32, 33] offer further efficient approximation methods for
+implementing CU, as required for particular practical use cases.
+4
+Data
+We describe the data set construction for replicating the empirical example for BL-APT of [4]. This con-
+struction matches the original descriptions as closely as possible, and we make note of any additional re-
+quired assumptions made. While we have attempted to carefully reproduce the database, our results need
+12
+
+0.10
+market beta
+size
+0.08
+volatility
+momentum
+0.06
+value
+cuml factor return
+0.04
+0.02
+0.00
+-0.02
+-0.04
+-0.06
+2011-01
+2011-03
+2011-05
+2011-07
+2011-09
+2011-11
+2012-01
+datenot match exactly. Not in the least, we have no guarantee that the underlying database that we call is the
+same 5 years later, even if our data replication process is perfectly faithful. A visual comparison can be
+made between our factor values against the source given Figure 3 above, which demonstrates a reasonable
+replication.
+The data is sourced fom CRSP and IBES databases with access granted via the Wharton Research Data
+Service. The original work sourced daily US equity market data from 1992-2015; we extend our data set till
+2022 to include the market crash of March 2020, and subsequent market rebound, for interest’s sake.
+For each day, set n = 2000 and select the top n stocks within the US market sorted by market capitalisation.
+The data set is filtered for USD denominated common stock only – there are no closed end funds, REITs,
+ETFs, unit trusts, depository receipts, warrants etc. We also collected the S&P500 (excess) return time-
+series, stock market capitalisations, and earnings per share, adjusted for splits.
+The data set requires the creation of 5 risk factors: market beta, size, volatility, momentum and value. The
+reasonableness of our data set construction is per the output of Figure 3, which accords with expectations.
+We also create 70 industry factors; these are one-hot encoded based on the industry given by SIC. Calculating
+size is relatively straightforward in CRSP as the product of shares outstanding and the daily close price.
+Value was determined by analysing IBES data, and could be merged back to the CRSP database based on
+the CUSIP identifier. We note that risk factor construction is often non-trivial. Momentum was codable
+using CRSP data and the definitions of [34]; we calculated the daily compounded 12 month returns sans the
+most recent 1 month of data. We created the market Beta and volatility factors using the relevant CRSP data
+and the details of [4]. Indeed, over a two year rolling window we estimate a collection of linear functions
+by regressing each asset’s daily excess returns against the S&P500 excess returns. The market Beta is the
+regression gradient, while the volatility factor is set to be the regression mean-square error.
+The data is constructed for bi-monthly rebalancing to facilitate the experiments of the following section.
+5
+Results
+View models. To proxy multiple sources of view generation, we implemented various models with utility
+for forecasting financial time-series. Indeed, machine learning models have proven useful for not only
+prediction, but also for estimating prediction uncertainty. We implement an ARIMA, boosted regression and
+Gaussian Process model for generating views, and calculate model-derived uncertainty estimates. Relevant
+details are included in the Appendix, since time-series prediction modelling is not the primary focus of this
+paper. We denote the three view models ‘ARIMA’, ‘Boost’ and ‘GP’, respectively. We also implement the
+4 fusion methods outlined in Section 3.
+Parameter choices. Per Figure 1 and the outline in Section 2, the BL-APT model requires the specification
+of q, F , Ω, ξ, V and D. We set q as the mean prediction estimate given by a view model, with the view
+models as previously described. The accompanying epistemic uncertainty estimate is set to Ω, and F is
+set equal to the aleatoric uncertainty estimate. The prior hyperparameter ξ is estimated as an average of f
+over a recent rolling lookback window of the most recent 20 observations. This window size was arbitraily
+decided, and is the same for all rolling windows introduced hereafter. The total variance of each underlying
+factor is calculated relative to out-of-sample data, and we yield an approximation to epistemic uncertainty
+by the estimation method as described for the ARIMA model in the Appendix below. We set V as this
+estimate. Our estimate for D is a diagonal covariance matrix equal to �σ2I, where �σ2 is the mean square
+error yielded from estimating eq. (7), and I is the identity matrix. Finally, we set the relative risk aversion
+parameter to a constant value of 10.
+Transaction costs. An effect of accounting for transaction costs, and carefully setting the transaction cost
+model parameters, is to greatly reduce portfolio turnover relative to the unconstrained Markowitz approach
+13
+
+Figure 4: View-based portfolio excess return performance net of trading costs. Benchmark SPX strategy is
+gross of (negligible) transaction costs, but total returns are calculated in excess of the risk-free rate.
+with costs assumed nil. Indeed, without transaction costs, it is well-known that this latter approach usually
+result in unrealistic and unreasonably large leverage suggested for the optimal portfolio, and high portfolio
+turnover. Recent results of [12] show that incorporating an appropriate transaction cost model goes some
+way to mitigate these limitations in empirical studies. We implement the model outlined in Section 2.4 above
+to the same ends. We set our portfolio rebalance period to be bi-monthly, which is sufficiently long – given
+our assumed wealth process, and the potential return being signficantly larger than the cost of rebalancing –
+such that the reward of updating weights is not dominated by the cost of trading.
+Results – benchmark. We have tabulated performance results by year and model over a 29 year period, and
+include them in the Appendix. The method ‘S&P500 (TR)’ denotes the total return of the S&P 500 for the
+year. The annual returns may appear slightly less than commonly reported since they are net of the risk-free
+rate. The S&P500 (TR) represents a useful benchmark in that it represents the market buy-and-hold strategy,
+accessible to the modern day investor and with a potential for exceptionally competitive fees, especially in
+the more recent years. For comparisons sake, all results dependent on an underlying view model are reported
+based on normalised underlying data, such that ex-post annualised return volatility is equal to that of the
+benchmark portfolio. We make a note that, on perusing the tables, there is obvious decay in the performance
+of the view-based models over the 30 year period, as evidenced, for example, by the significant decline in
+Sharpe ratios over time.
+Results – statistics. We depict the Sharpe ratio statistics from the tabulated data in Figure 4 above. The left-
+most chart shows box & whisker plots for the annual Sharpe ratio for the collection of portfolio’s over the 29
+year period. Investment in the S&P500 (TR) is clearly superior to our underlying modeling approach. On the
+other hand, there are improvements that could increase the view model performance that we deem beyond
+the scope of this work. For an easier comparison of centrality for the various method’s Sharpe distributions,
+we show each portfolio’s median and mean Sharpe ratio over the 29 year period in the right-most chart.
+This visual depiction summarises how fusion and non-fusion based methods performed relative to each
+other through time (and relative to the market total return portfolio). We observe that fusion-based medians
+14
+
+median
+mean
+3
+0.8 
+0.6
+0.2 -
+-2
+0.0 -
+ARIMA
+GP
+Boost
+PW
+CU
+ICI
+SPX
+ARIMA
+GP
+Boost
+PW
+CU
+ICI
+SPX
+Method
+Methodare increasing through PW (0.11), CU (0.16), CI (0.38) and ICI (0.48), with the means showing a similar but
+less pronounced trend. The set of mean Sharpe ratios for the single-view based methods have a smaller range
+than the medians (0.21-0.30 versus 0.01–0.53, respectively); similarly for the fusion-based methods (0.17–
+0.31 versus 0.11–0.48). When considering the mean Sharpe ratio over the full data sample, ICI outperforms
+amongst the set of fusion-based methods and the single-view-based models. Similarly to the median, ICI
+outperforms amongst the set of fusion-based methods and sits closely to the best of the single-view-based
+models. We test for statistical significance of differences in these measures of distribution centrality per the
+results in Figure 5 below. Despite the small sample sizes there is some interesting supporting evidence for
+the outperformance of fusion-based methods.
+We test for the difference of means between methods with a collection of pairwise 1-sided t-tests. Such
+tests make a critical assumption of independence in the pairwise Sharpe ratio differences as indexed by year.
+We note that despite individual time-series of model performance statistics potentially displaying serial
+correlation, it seems reasonable to suggest that the the performance between models over the years does
+not. This is clearly a critical claim. We examine the autocorrelation function for the 28 possible pairwise
+comparisons and find 1 case of rejecting the null hypothesis of no autocorrelation in a Ljung-Box test at
+the 10% level of significance. We further assume normality of the differences and test this with a (one-
+sided) Shapiro-Wilk test for normality, also at the 10% level of significance. We find that this assumption
+is rejected for 3 cases. Finally, we assume the non-existence of outliers in the difference data, and validate
+this claim on visual inspection of box and whisker plots.
+On testing for the difference of means with a paired-t test, we find, of particular interest, that ICI outperforms
+the ARIMA and GP models, while CI outperforms the ARIMA only (though in this case the Shaprio-
+Wilks test leads us not to rely on some of the t-test p-values). To support testing for significance in the
+difference of means between groups, we bootstrap 2-sided bias-corrected and accelerated (BCa) bootstrap
+90% confidence intervals for paired data [35]. We find evidence that ICI outperforms the ARIMA and GP
+models, and again the CI outperforms the ARIMA model. We also test for the difference in medians between
+groups with BCa confidence intervals, but they are broadly less conclusive. This is potentially owing to the
+small sample size. On the other hand, we have evidence that both ICI and CI outperforms GP on this metric.
+Alternatively to testing for the difference of medians across all samples, we can test for the median of the
+differences between pairwise annual Sharpes. To this end, we utilise the Wilcoxon signed-rank test for
+paired samples [36]. In addition to assuming independence, a critical assumption is that of symmetry about
+the distributions of paired differences. Given the results of the Shapiro-Wilk tests, and visual inspection of
+what appear to be reasonable QQ plots, we continue assuming symmetry is satisfied. We perform 1-sided
+tests at the 10% level of signficance and find evidence that ICI outperforms the ARIMA model for this
+comparison.
+It is interesting that the CI and ICI methods achieve more compelling outperformance than the CU and PW
+fusion methods, relative to the underlying view models. The assumption of PW that the underlying views
+have 0 cross-covariance may be suboptimal, such that the method is yielding inconsistent estimates and in
+turn impacting trading performance. On the other hand, perhaps CU could be utilised more sparingly and
+strategically, such as when the underlying views have relatively high dispersion and so appear sufficiently
+contradictory. An alternative fusion method such as ICI could be employed otherwise.
+Corroborating our intuition about the relative strength of the S&P500 (TR) strategy relative to all others, we
+see that SPX improves on all models – both single-view- and fusion-based – for almost all tests. Sufficiently
+strong view models are required to compete with the market portfolio, but beyond the scope of this work. It
+is perhaps surprising that view- and fusion-based models net of transaction costs have net positive Sharpe
+ratios at all. Indeed, we estimate global Sharpe ratios between 0.10 (PW) and 0.34 (ICI) for the entirety of
+the 29 year period.
+15
+
+Pairwise
+comparison
+Ljung-Box
+Shapiro-Wilk
+paired-t p-vals
+(diff of means)
+BCa CIs
+(diff of means)
+BCa CIs
+(diff of med.)
+Wilcoxon p-vals
+(med. of diffs)
+SPX
+ICI
+0.14
+0.21
+0.06
+[ 0.15, 0.98 ]
+[ -0.13, 0.90 ]
+0.07
+CI
+0.14
+0.45
+0.05
+[ 0.15, 0.99 ]
+[ -0.07, 0.70 ]
+0.07
+CU
+0.12
+0.75
+0.05
+[ 0.19, 1.01 ]
+[ 0.31, 1.03 ]
+0.06
+PW
+0.17
+0.36
+0.03
+[ 0.29, 1.22 ]
+[ 0.07, 1.30 ]
+0.06
+ARIMA
+0.13
+0.41
+0.03
+[ 0.25, 1.09 ]
+[ 0.17, 0.92 ]
+0.03
+GP
+0.17
+0.51
+0.03
+[ 0.20, 1.09 ]
+[ 0.34, 1.10 ]
+0.03
+Boost
+0.16
+0.32
+0.05
+[ 0.18, 1.01 ]
+[ -0.10, 0.83 ]
+0.08
+ICI
+CI
+0.80
+0.03
+0.47
+[ -0.08, 0.08 ]
+[ -0.26, 0.28 ]
+0.31
+CU
+0.88
+0.12
+0.41
+[ -0.11, 0.14 ]
+[ 0.01, 0.67 ]
+0.63
+PW
+0.94
+0.90
+0.15
+[ -0.03, 0.32 ]
+[ 0.04, 1.00 ]
+0.19
+ARIMA
+0.70
+0.75
+0.08
+[ 0.02, 0.21 ]
+[ -0.26, 0.36 ]
+0.10
+GP
+0.33
+0.65
+0.09
+[ 0.01, 0.19 ]
+[ 0.25, 0.73 ]
+0.12
+Boost
+0.68
+0.19
+0.46
+[ -0.21, 0.25 ]
+[ -0.51, 0.39 ]
+0.58
+CI
+CU
+0.56
+0.85
+0.43
+[ -0.12, 0.14 ]
+[ 0.05, 0.51 ]
+0.55
+PW
+0.67
+0.56
+0.15
+[ -0.02, 0.32 ]
+[ -0.29, 0.65 ]
+0.18
+ARIMA
+0.47
+0.00
+0.06
+[ 0.03, 0.19 ]
+[ -0.17, 0.22 ]
+0.93
+GP
+0.11
+0.74
+0.13
+[ -0.01, 0.20 ]
+[ 0.30, 0.67 ]
+0.16
+Boost
+0.35
+0.91
+0.47
+[ -0.17, 0.24 ]
+[ -0.52, 0.10 ]
+0.50
+CU
+PW
+0.29
+0.28
+0.17
+[ -0.04, 0.28 ]
+[ -0.57, 0.43 ]
+0.17
+ARIMA
+0.48
+0.89
+0.23
+[ -0.05, 0.22 ]
+[ -0.46, -0.02 ]
+0.20
+GP
+0.75
+0.22
+0.23
+[ -0.06, 0.20 ]
+[ -0.13, 0.37 ]
+0.21
+Boost
+0.73
+0.98
+0.49
+[ -0.21, 0.19 ]
+[ -0.78, 0.01 ]
+0.52
+PW
+ARIMA
+0.95
+0.64
+0.36
+[ -0.17, 0.11 ]
+[ -0.65, 0.24 ]
+0.65
+GP
+0.95
+0.58
+0.33
+[ -0.19, 0.08 ]
+[ -0.31, 0.66 ]
+0.41
+Boost
+0.17
+0.45
+0.09
+[ -0.27, -0.03 ]
+[ -1.12, -0.14 ]
+0.10
+ARIMA
+GP
+0.01
+0.94
+0.46
+[ -0.08, 0.07 ]
+[ 0.22, 0.54 ]
+0.45
+Boost
+0.20
+0.06
+0.27
+[ -0.29, 0.09 ]
+[ -0.51, 0.19 ]
+0.73
+GP
+Boost
+0.74
+0.34
+0.27
+[ -0.26, 0.07 ]
+[ -0.96, -0.32 ]
+0.64
+Figure 5: Tabulated p-values and confidence intervals for a battery of statistical tests for comparing annual 29 years of annual Sharpe ratios pairwise
+between strategies. Yellow highlighting is applied for significance at the 10% level. The rightmost four columns represent one-sided tests.
+16
+
+Closing remark. The results presented offer preliminary evidence supporting fusion-based methods within
+a Black-Litterman framework subsuming a relatively complex investment strategy net of transaction costs.
+Fusion-based methods result in a weighted-average performance respectful of uncertainty estimates. These
+methods could certainly be ex-ante preferred when all views are to be incorporated into an investment de-
+cision, in the case that the best view model is unknown (and/or as in our presented work, when the method
+constituting the best view model is both largely unpredictable, and changing throught time). We have sup-
+porting evidence for a rare ‘free lunch’ in financial investing by way of model fusion, essentially amounting
+to a benefit we could call ‘model diversification’. This could be of further application in alternative trad-
+ing domains, perhaps with more sophisticated underlying view models, and we hope to inspire readers to
+consider their practical use.
+6
+Conclusion and next steps
+In this work, we further characterise view uncertainty within a Bayesian Black-Litterman framework. In
+doing so, we offer optimal portfolio weights for a case of Black-Litterman in an Arbitrage Pricing Theory
+setting. Considering the Bayesian Black-Litterman model via an equivalent state-space representation, we
+are inspired by the information fusion literature for combining correlated prediction mean and uncertainty
+estimates streamed from diverse sources. Hence, we demonstrate prediction and uncertainty fusion for
+multiple, simultaneous views within the Black-Litterman framework, and describe consistent uncertainty
+estimation within financial investing contexts. In our empirical work, we demonstrate the utility of our
+approach for BL-APT. Future practical work could be based on more realistic investment strategies, not the
+least incorporating methods of drawdown control.
+Acknowledgements
+The authors would like to thank the Oxford-Man Institute of Quantitative Finance for its generous support.
+Professor Stephen Roberts would like to further thank the Royal Academy of Engineering. Trent Spears
+would like to further thank Professor Nir Vulkan and Dr Jan-Peter Calliess for their helpful comments and
+suggestions.
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+19
+
+A
+Appendix
+A.1
+Further APT calculations
+This section adds further detail to the calculations of Section 2.3. In determining the expectation and covariance for
+r|q in the case of unknown mean but known covariance, given eq. (12) we collect and expand the terms in the exponent
+up to a factor of − 1
+2, complete the square in f, and integrate what is recognisable as a Gaussian integral:
+(r − Xf)T D−1(r − Xf) + (f − µ)T Σ−1(f − µ) = rT D−1r − 2f T XT D−1r
++ (Xf)T D−1Xf + f T Σ−1f − 2f T Σ−1µ + µT Σ−1µ
+= rT D−1r + f T Hf − 2ηf + µT Σ−1µ
+where µ and Σ denote the mean and covariance for f|q, H := XT D−1X + Σ−1 and η := XT D−1r + Σ−1µ.
+Completing the square,
+f T Hf − 2f T η = (f − ν)T H(f − ν) − νT Hν,
+ν = H−1η,
+whereby
+�
+exp
+�
+− 1
+2(f − ν)T H(f − ν)
+�
+df =
+�
+(2π)k
+|H| .
+Therefore
+p(r|q) ∝ exp
+�
+− 1
+2
+�
+rT D−1r + µT Σ−1µ − νT Hν
+��
+= exp
+�
+− 1
+2
+�
+rT D−1r + µT Σ−1µ − ηT H−1η
+��
+,
+(32)
+and we retrieve the exponent of the Gaussian for r|q. Inspired by [4], we next make use of the following Lemma:
+Lemma 1. If a multivariate normal random variable θ has density p(θ) and −2 log p(θ) = θ′Hθ − 2ν′θ +
+(terms without θ) then var(θ) = H−1 and Eθ = H−1ν.
+Collecting quadratic terms in r from the exponent of eq. (32):
+−ηT H−1η + rT D−1r = −[XT D−1r + Σ−1µ]T H−1[XT D−1r + Σ−1µ] + rT D−1r
+= −rT D−1XH−1XT D−1r + rT D−1r + lower-order terms in r
+(33)
+= rT [−D−1XH−1XT D−1 + D−1]r + lower-order terms in r
+Making use of the lemma, we have that the posterior predictive distribution p(r|q) is multivariate normal with covari-
+ance
+var(r|q) = [−D−1XH−1XT D−1 + D−1]−1,
+= [D−1 − D−1X[XT D−1X + [(V −1 + Ω−1)−1 + F ]−1]−1XT D−1]−1.
+Futher, we collect the linear terms in r from eq. (33):
+−rT D−1XT H−1Σ−1µ − µT Σ−1H−1XT D−1r = −2µT Σ−1H−1XT D−1r,
+so that again by the lemma
+E(r|q) = var(r|q)D−1XH−1Σ−1µ
+= var(r|q)D−1X[XT D−1X + [(V −1 + Ω−1)−1 + F ]−1]−1
+· [(V −1 + Ω−1)−1 + F ]−1(V −1 + Ω−1)−1(V −1ξ + Ω−1q).
+20
+
+A.2
+View fusion under model-based forecasts
+Suppose we model y = f(x) + ϵ for some function f parameterised by θ, with ϵ ∼ N(0, σ2). Then we can write
+y|x, θ ∼ N(f(x), σ2). Assuming θ has prior distribution p(θ), then for a collection of data D we can update the prior
+via the likelihood analogous to eq. (5) above: p(θ|D) ∝ p(D|θ)p(θ). Then for a new data point x∗, the predictive
+distribution for the corresponding y∗ can be written
+p(y∗|x∗, D) =
+�
+p(y∗|x∗, θ)p(θ|D)dθ.
+Further, the variance of the prediction, var(y∗|x∗, D), can be decomposed making use of the law of total variance, that
+is:
+var(y∗|x∗, D) = varθ|D
+�
+E(y∗|x∗, θ)
+�
++ Eθ|D
+�
+var(y∗|x∗, θ)
+�
+.
+(34)
+Here the subscript on the outer variance and expectation terms on the right-hand side denotes that the integral is
+calculated with respect to the conditional density for θ|D. The first term on the right-hand side we call the epistemic
+uncertainty, sometimes described as a ‘model’ uncertainty associated with estimating the model parameters, and that
+is reducible with increasing data. The second term we call the aleatoric uncertainty; this models the underlying
+stochasticity of the data distribution, and is irreducible.
+Estimation of predictive distributions or the components of model uncertainty is not always tractable; consequently,
+various approximation methods exists for estimating these quantities. A review is beyond the scope of this paper; we
+instead refer interested readers to the recent work of [37] for further details.
+A.2.1
+Brief overview of view models
+To yield the results of Section 5 above we first implement three diverse view models. For completeness, we provide
+the implementation details below.
+We implement a Gaussian Process model using scikit-learn in Python [38]. The kernel function is given by the sum
+of a radial basis function and a white-noise kernel; see, for example, [39] for context on Gaussian Processes for time-
+series modelling. We re-fit the model on a bi-monthly basis on a rolling data window of 1 year. The predict method
+is used to generate prediction estimates and an accompanying (total) uncertainty estimate. The uncertainty can be
+decomposed into epistemic and aleatoric components by setting the latter as the noise-level parameter estimated for
+the white-noise kernel. By eq. (34) above, the epistemic uncertainty is then the difference between the total uncertainty
+and the aleatoric uncertainty estimates.
+We implement a boosted regression model making use of CatBoost [40]. We re-fit the model on a bi-monthly basis
+on a rolling data window of 2 years. The model yields an aleatoric uncertainty estimate owing to modelling this
+uncertainty directly via the loss function. An estimate for epistemic uncertainty is approximated by the variance of the
+underlying ensemble of predictions. Further details of this method can be found in [41].
+We estimate an ARIMA model for view generation as a well-known baseline model. Further, this model naturally
+yields an aleatoric uncertainty estimate. To approximate epistemic uncertainty for this model, we are inspired by
+Algorithm 3 of [42]. We note that our method is somewhat ad hoc, and has subtle differences: we estimate prediction
+error variance on a recent out-of-sample lookback window of size 6 months, estimating epistemic uncertainty as the
+difference between this term and today’s aleatoric uncertainty estimate, to a minimum of 1e-8. We re-fit the model on
+a bi-monthly basis on a rolling data window of 1 year.
+21
+
+A.3
+Performance results by year
+Performance metrics for market total return (in excess of the risk-free rate), against a collection of Black-Litterman
+models with varying underlying prediction methods to generate and/or fuse views. Methods sans the index allocation
+are normalised by return volatility to equal the ex-post annual return volatility of the market index.
+1993
+1994
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+7.11
+8.59
+0.82
+-1.94
+1.21
+-8.84
+-2.03
+9.80
+-0.21
+-1.42
+-0.28
+-8.91
+ARIMA
+-17.50
+8.59
+-2.04
+-2.68
+-2.01
+-16.43
+20.00
+9.80
+2.04
+1.73
+5.65
+-18.76
+GP
+-15.42
+8.59
+-1.79
+-2.60
+-1.78
+-15.90
+21.39
+9.80
+2.18
+1.78
+5.91
+-19.92
+Boost
+-9.14
+8.59
+-1.06
+-1.84
+-1.18
+-10.40
+12.53
+9.80
+1.28
+1.04
+2.73
+-13.63
+PW
+-12.04
+8.59
+-1.40
+-2.20
+-1.44
+-12.37
+13.90
+9.80
+1.42
+1.16
+3.07
+-14.73
+CU
+-11.11
+8.59
+-1.29
+-1.98
+-1.47
+-13.29
+20.65
+9.80
+2.11
+1.74
+5.76
+-19.13
+CI
+-20.11
+8.59
+-2.34
+-2.81
+-2.22
+-18.60
+18.24
+9.80
+1.86
+1.59
+6.13
+-17.71
+ICI
+-16.51
+8.59
+-1.92
+-2.46
+-1.82
+-16.14
+19.94
+9.80
+2.03
+1.70
+8.08
+-18.73
+1995
+1996
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+26.80
+7.81
+3.43
+-2.57
+5.72
+-24.15
+16.31
+11.75
+1.38
+-1.60
+1.96
+-18.96
+ARIMA
+-12.74
+7.81
+-1.63
+-4.48
+-1.67
+-14.11
+14.18
+11.75
+1.21
+-0.33
+2.78
+-19.34
+GP
+-11.30
+7.81
+-1.45
+-4.33
+-1.52
+-13.81
+9.49
+11.75
+0.81
+-0.59
+1.65
+-16.73
+Boost
+-15.45
+7.81
+-1.98
+-4.56
+-2.06
+-14.93
+10.90
+11.75
+0.93
+-0.49
+1.62
+-18.25
+PW
+-21.30
+7.81
+-2.73
+-5.36
+-2.46
+-20.11
+9.34
+11.75
+0.79
+-0.60
+1.34
+-19.69
+CU
+-11.64
+7.81
+-1.49
+-4.53
+-1.57
+-14.14
+20.40
+11.75
+1.74
+0.02
+4.69
+-22.35
+CI
+-13.29
+7.81
+-1.70
+-4.87
+-1.77
+-14.72
+25.06
+11.75
+2.13
+0.29
+6.07
+-25.21
+ICI
+-12.45
+7.81
+-1.59
+-4.78
+-1.67
+-14.07
+21.15
+11.75
+1.80
+0.06
+4.78
+-23.72
+1997
+1998
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+25.34
+18.09
+1.40
+-1.04
+2.04
+-23.74
+22.47
+20.25
+1.11
+-0.51
+1.57
+-22.93
+ARIMA
+26.74
+18.09
+1.48
+-0.05
+3.39
+-21.90
+12.62
+20.25
+0.62
+-0.34
+0.91
+-16.82
+GP
+31.28
+18.09
+1.73
+0.17
+3.71
+-25.04
+10.57
+20.25
+0.52
+-0.38
+0.73
+-16.72
+Boost
+32.70
+18.09
+1.81
+0.22
+4.57
+-26.85
+5.64
+20.25
+0.28
+-0.58
+0.41
+-19.44
+PW
+30.50
+18.09
+1.69
+0.13
+3.69
+-26.26
+15.04
+20.25
+0.74
+-0.24
+1.06
+-15.90
+CU
+28.95
+18.09
+1.60
+0.05
+3.75
+-23.06
+29.10
+20.25
+1.44
+0.22
+2.41
+-27.24
+CI
+23.15
+18.09
+1.28
+-0.22
+2.61
+-18.85
+17.15
+20.25
+0.85
+-0.18
+1.24
+-16.74
+ICI
+28.57
+18.09
+1.58
+0.04
+3.58
+-22.90
+26.14
+20.25
+1.29
+0.12
+2.20
+-24.05
+1999
+2000
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+16.15
+18.04
+0.90
+-3.27
+1.34
+-14.82
+-12.80
+22.18
+-0.58
+-0.50
+-0.81
+-20.07
+ARIMA
+-28.79
+18.05
+-1.60
+-1.72
+-1.71
+-27.22
+-5.65
+22.17
+-0.25
+-0.10
+-0.33
+-26.38
+GP
+-21.79
+18.05
+-1.21
+-1.58
+-1.40
+-22.85
+-8.89
+22.17
+-0.40
+-0.23
+-0.51
+-26.27
+Boost
+19.04
+18.05
+1.06
+-0.12
+1.64
+-25.24
+-29.64
+22.17
+-1.34
+-0.83
+-1.55
+-38.33
+PW
+-9.48
+18.05
+-0.53
+-1.13
+-0.68
+-20.84
+-10.81
+22.17
+-0.49
+-0.32
+-0.64
+-27.58
+CU
+-3.66
+18.05
+-0.20
+-0.94
+-0.27
+-21.42
+1.46
+22.17
+0.07
+0.15
+0.09
+-24.08
+CI
+-19.29
+18.05
+-1.07
+-1.39
+-1.27
+-20.96
+6.15
+22.17
+0.28
+0.34
+0.39
+-23.62
+ICI
+-32.13
+18.05
+-1.78
+-1.89
+-1.89
+-30.89
+-6.63
+22.17
+-0.30
+-0.12
+-0.38
+-27.23
+Figure 6: Performance metrics, 1993-2000.
+22
+
+2001
+2002
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+-14.12
+21.51
+-0.67
+-2.25
+-0.92
+-30.91
+-23.24
+25.99
+-0.89
+-1.43
+-1.28
+-33.81
+ARIMA
+36.09
+21.51
+1.68
+1.72
+2.57
+-35.22
+26.07
+25.99
+1.00
+1.49
+1.53
+-34.82
+GP
+36.18
+21.51
+1.68
+1.67
+2.60
+-34.88
+33.51
+25.99
+1.29
+1.73
+2.10
+-37.44
+Boost
+25.65
+21.51
+1.19
+1.34
+1.64
+-30.70
+31.67
+25.99
+1.22
+1.65
+1.99
+-36.37
+PW
+23.71
+21.51
+1.10
+1.28
+1.48
+-29.85
+33.17
+25.99
+1.28
+1.68
+2.09
+-37.85
+CU
+21.26
+21.51
+0.99
+1.24
+1.39
+-26.00
+4.75
+25.99
+0.18
+0.83
+0.24
+-30.08
+CI
+35.16
+21.51
+1.63
+1.66
+2.62
+-33.08
+22.01
+25.99
+0.85
+1.37
+1.28
+-31.67
+ICI
+34.26
+21.51
+1.59
+1.64
+2.52
+-33.28
+26.35
+25.99
+1.01
+1.48
+1.57
+-35.08
+2003
+2004
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+25.64
+17.04
+1.50
+-2.42
+2.32
+-28.43
+9.78
+11.07
+0.88
+-1.37
+1.28
+-12.49
+ARIMA
+-23.61
+17.03
+-1.39
+-2.48
+-1.53
+-23.77
+14.26
+11.07
+1.29
+0.26
+2.62
+-15.21
+GP
+-27.81
+17.03
+-1.63
+-2.70
+-1.73
+-26.21
+15.63
+11.07
+1.41
+0.35
+3.08
+-16.01
+Boost
+-31.93
+17.03
+-1.87
+-2.76
+-1.95
+-30.85
+12.73
+11.07
+1.15
+0.16
+2.41
+-14.50
+PW
+-31.18
+17.03
+-1.83
+-2.80
+-1.86
+-29.23
+14.71
+11.07
+1.33
+0.30
+3.02
+-14.74
+CU
+-20.25
+17.03
+-1.19
+-2.60
+-1.28
+-22.22
+12.98
+11.07
+1.17
+0.17
+2.22
+-15.10
+CI
+-20.35
+17.03
+-1.19
+-2.32
+-1.36
+-21.51
+12.22
+11.07
+1.10
+0.13
+2.18
+-14.11
+ICI
+-21.49
+17.03
+-1.26
+-2.39
+-1.40
+-22.16
+16.73
+11.07
+1.51
+0.43
+3.21
+-15.57
+2005
+2006
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+2.37
+10.26
+0.23
+-3.66
+0.33
+-9.87
+10.49
+10.02
+1.05
+-3.14
+1.59
+-12.93
+ARIMA
+3.65
+10.27
+0.36
+-0.24
+0.52
+-9.98
+-3.92
+10.02
+-0.39
+-1.17
+-0.58
+-15.33
+GP
+-0.49
+10.27
+-0.05
+-0.57
+-0.07
+-11.40
+-2.43
+10.02
+-0.24
+-1.03
+-0.36
+-14.76
+Boost
+1.49
+10.27
+0.15
+-0.42
+0.22
+-11.54
+-4.06
+10.02
+-0.41
+-1.14
+-0.58
+-15.78
+PW
+0.10
+10.27
+0.01
+-0.53
+0.01
+-12.06
+-6.36
+10.02
+-0.63
+-1.33
+-0.87
+-16.78
+CU
+1.58
+10.27
+0.15
+-0.44
+0.23
+-10.15
+3.40
+10.02
+0.34
+-0.59
+0.61
+-13.37
+CI
+1.62
+10.27
+0.16
+-0.41
+0.22
+-10.65
+-2.07
+10.02
+-0.21
+-1.02
+-0.32
+-14.31
+ICI
+1.23
+10.27
+0.12
+-0.45
+0.17
+-9.78
+1.52
+10.02
+0.15
+-0.74
+0.27
+-12.77
+2007
+2008
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+2.07
+15.96
+0.13
+-4.06
+0.17
+-10.66
+-39.34
+40.88
+-0.96
+-0.77
+-1.31
+-47.78
+ARIMA
+-1.06
+15.96
+-0.07
+-0.33
+-0.10
+-12.74
+17.00
+40.88
+0.42
+1.12
+0.60
+-42.30
+GP
+-1.52
+15.96
+-0.10
+-0.35
+-0.14
+-13.27
+46.05
+40.88
+1.13
+1.69
+1.83
+-40.38
+Boost
+-3.80
+15.96
+-0.24
+-0.48
+-0.35
+-15.23
+39.48
+40.88
+0.97
+1.34
+1.56
+-43.34
+PW
+1.83
+15.96
+0.11
+-0.21
+0.18
+-14.36
+56.22
+40.88
+1.38
+1.81
+2.61
+-46.29
+CU
+-13.65
+15.96
+-0.86
+-0.87
+-1.09
+-17.35
+67.57
+40.88
+1.65
+2.27
+3.13
+-51.49
+CI
+-3.35
+15.96
+-0.21
+-0.44
+-0.31
+-11.66
+47.33
+40.88
+1.16
+1.79
+2.16
+-42.41
+ICI
+-0.99
+15.96
+-0.06
+-0.31
+-0.08
+-9.66
+60.76
+40.88
+1.49
+2.33
+2.91
+-49.16
+Figure 7: Performance metrics, 2001-2008.
+23
+
+2009
+2010
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+27.09
+27.22
+1.00
+-0.83
+1.45
+-41.01
+15.47
+18.02
+0.86
+-1.81
+1.23
+-19.54
+ARIMA
+17.54
+27.22
+0.64
+-0.13
+1.13
+-21.65
+-41.11
+18.02
+-2.28
+-2.30
+-2.19
+-37.28
+GP
+7.78
+27.22
+0.29
+-0.43
+0.48
+-18.56
+-42.99
+18.02
+-2.38
+-2.42
+-2.33
+-38.98
+Boost
+-33.40
+27.22
+-1.23
+-1.76
+-1.51
+-35.25
+-33.99
+18.02
+-1.89
+-2.07
+-1.97
+-33.55
+PW
+-9.72
+27.22
+-0.36
+-1.00
+-0.55
+-19.77
+-36.86
+18.02
+-2.04
+-2.17
+-2.06
+-34.57
+CU
+19.15
+27.22
+0.70
+-0.08
+1.30
+-21.64
+-36.30
+18.02
+-2.01
+-2.14
+-2.03
+-35.08
+CI
+25.99
+27.22
+0.95
+0.12
+1.52
+-31.85
+-37.32
+18.02
+-2.07
+-2.14
+-1.98
+-34.19
+ICI
+27.58
+27.22
+1.01
+0.17
+1.74
+-27.00
+-38.24
+18.02
+-2.12
+-2.16
+-1.99
+-33.98
+2011
+2012
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+4.78
+23.24
+0.21
+0.83
+0.28
+-18.64
+15.63
+12.73
+1.24
+-0.23
+1.89
+-14.23
+ARIMA
+-29.76
+23.24
+-1.28
+-1.08
+-1.35
+-34.76
+22.54
+12.73
+1.77
+0.46
+3.23
+-19.67
+GP
+-29.17
+23.24
+-1.26
+-1.03
+-1.33
+-33.83
+29.53
+12.73
+2.32
+0.86
+5.28
+-25.51
+Boost
+-8.30
+23.24
+-0.36
+-0.41
+-0.45
+-18.13
+28.89
+12.73
+2.27
+0.83
+5.22
+-25.12
+PW
+-8.41
+23.24
+-0.36
+-0.42
+-0.48
+-16.08
+25.43
+12.73
+2.00
+0.65
+4.23
+-24.06
+CU
+-15.96
+23.24
+-0.69
+-0.56
+-0.80
+-29.10
+15.64
+12.73
+1.23
+0.09
+1.79
+-15.94
+CI
+-34.31
+23.24
+-1.48
+-1.19
+-1.53
+-32.76
+19.15
+12.73
+1.50
+0.28
+2.45
+-18.43
+ICI
+-26.26
+23.24
+-1.13
+-0.92
+-1.18
+-33.43
+18.62
+12.73
+1.46
+0.25
+2.45
+-16.55
+2013
+2014
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+28.68
+11.05
+2.60
+-1.62
+3.96
+-22.78
+13.48
+11.33
+1.19
+1.09
+1.67
+-18.27
+ARIMA
+2.61
+11.05
+0.24
+-1.74
+0.34
+-11.82
+8.11
+11.33
+0.72
+-0.35
+1.74
+-10.11
+GP
+-4.37
+11.05
+-0.40
+-2.45
+-0.51
+-16.53
+7.28
+11.33
+0.64
+-0.42
+1.33
+-8.94
+Boost
+7.30
+11.05
+0.66
+-1.47
+0.96
+-8.04
+16.40
+11.33
+1.45
+0.18
+3.85
+-15.84
+PW
+-1.12
+11.05
+-0.10
+-2.36
+-0.14
+-14.72
+14.34
+11.33
+1.27
+0.05
+3.14
+-14.43
+CU
+-11.24
+11.05
+-1.02
+-2.96
+-1.17
+-19.21
+1.81
+11.33
+0.16
+-0.79
+0.29
+-7.87
+CI
+4.64
+11.05
+0.42
+-1.57
+0.63
+-9.25
+6.04
+11.33
+0.53
+-0.47
+1.26
+-9.70
+ICI
+-3.97
+11.05
+-0.36
+-2.40
+-0.47
+-15.92
+7.34
+11.33
+0.65
+-0.39
+1.43
+-9.50
+2015
+2016
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+2.57
+15.46
+0.17
+0.91
+0.23
+-12.04
+11.94
+13.07
+0.91
+-1.32
+1.30
+-20.80
+ARIMA
+29.50
+15.46
+1.91
+1.56
+2.82
+-24.32
+-0.11
+13.07
+-0.01
+-0.90
+-0.01
+-11.81
+GP
+25.13
+15.46
+1.62
+1.34
+2.52
+-24.29
+0.75
+13.07
+0.06
+-0.84
+0.11
+-12.31
+Boost
+28.98
+15.46
+1.87
+1.47
+3.17
+-26.31
+-3.25
+13.07
+-0.25
+-1.08
+-0.39
+-10.62
+PW
+28.45
+15.46
+1.84
+1.56
+2.77
+-26.20
+-11.84
+13.07
+-0.91
+-1.60
+-1.22
+-12.92
+CU
+31.35
+15.46
+2.03
+1.83
+2.96
+-26.59
+-1.96
+13.07
+-0.15
+-1.01
+-0.25
+-12.55
+CI
+27.01
+15.46
+1.75
+1.45
+2.56
+-22.93
+2.62
+13.07
+0.20
+-0.73
+0.38
+-13.80
+ICI
+22.50
+15.46
+1.46
+1.12
+2.42
+-23.22
+6.23
+13.07
+0.48
+-0.52
+1.03
+-13.95
+Figure 8: Performance metrics, 2009-2016.
+24
+
+2017
+2018
+Portfolio method
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+Cuml Ret
+Ret Vol
+Sharpe
+IR
+Sortino
+Max DD
+S&P 500 (TR)
+19.16
+6.67
+2.89
+-1.04
+4.55
+-17.04
+-4.81
+17.03
+-0.28
+-0.77
+-0.37
+-19.81
+ARIMA
+-1.08
+6.67
+-0.16
+-2.14
+-0.24
+-7.76
+4.96
+17.03
+0.29
+0.50
+0.40
+-14.97
+GP
+0.06
+6.67
+0.01
+-2.03
+0.02
+-5.84
+-0.59
+17.03
+-0.03
+0.26
+-0.04
+-14.22
+Boost
+-3.86
+6.67
+-0.58
+-2.50
+-0.79
+-10.74
+6.59
+17.03
+0.39
+0.61
+0.56
+-16.52
+PW
+-7.71
+6.67
+-1.16
+-2.99
+-1.41
+-12.44
+13.39
+17.03
+0.79
+0.87
+1.17
+-17.03
+CU
+-0.88
+6.67
+-0.13
+-2.16
+-0.20
+-6.45
+7.20
+17.03
+0.42
+0.57
+0.57
+-12.90
+CI
+2.51
+6.67
+0.38
+-1.75
+0.61
+-6.02
+2.18
+17.03
+0.13
+0.37
+0.17
+-12.58
+ICI
+4.71
+6.67
+0.71
+-1.48
+1.32
+-4.78
+-5.87
+17.03
+-0.34
+0.05
+-0.44
+-14.05
+2019
+2020
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+Figure 9: Performance metrics, 2017-2021.
+25
+
diff --git a/z9FRT4oBgHgl3EQfkDeO/content/tmp_files/load_file.txt b/z9FRT4oBgHgl3EQfkDeO/content/tmp_files/load_file.txt
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@@ -0,0 +1,2310 @@
+filepath=/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf,len=2309
+page_content='View fusion vis-`a-vis a Bayesian interpretation of Black-Litterman  for portfolio allocation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Trent Spears*†, Stefan Zohren∗, Stephen Roberts∗  February 1, 2023  Summary  The Black-Litterman model extends the framework of the Markowitz Modern Portfolio Theory to in-  corporate investor views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We consider a case where multiple view estimates, including uncertainties,  are given for the same underlying subset of assets at a point in time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This motivates our consideration  of data fusion techniques for combining information from multiple sources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In particular, we consider  consistency-based methods that yield fused view and uncertainty pairs;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' such methods are not common to  the quantitative finance literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We show a relevant, modern case of incorporating machine learning  model-derived view and uncertainty estimates, and the impact on portfolio allocation, with an example  subsuming Arbitrage Pricing Theory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Hence we show the value of the Black-Litterman model in combi-  nation with information fusion and artificial intelligence-grounded prediction methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Keywords: Black-Litterman portfolio allocation, information fusion, machine learning, financial time-  series analysis.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  1  Introduction  The Black-Litterman model extends the Markowitz portfolio optimisation framework to incorporate investor  beliefs about asset returns [1].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Such beliefs are termed ‘views’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In its original formulation, the Black-  Litterman framework is such that a given view induces an update of a prior assumption about the mean  parameter of a Gaussian return distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Making use of views in this way can result in non-trivial  differences to the estimated weights of a portfolio allocation strategy, and hence the relative investment  outcome.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Views can be obtained from diverse sources, including market pundit opinions, Reserve Bank statements,  and as output of statistical models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Consequently, in practice, a portfolio manager or trader may possess  multiple views about the same underlying asset, or subset of assets, over the next investment period.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A  contribution of this work is to both consider and extend the Black-Litterman framework to incorporate  multiple such views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  It is natural to formalise elements of the Black-Litterman model with respect to ideas from Bayesian statis-  tics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' See [2] for a review summary, with [3, 4] intriguing supplements.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We note that the modelling of this  paper presupposes the canonical Bayes-based Black-Litterman formalism.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This approach is useful for prac-  titioners in allowing for a strong theoretical grounding of the model prior in the Capital Asset Pricing Model  (CAPM) [5], and for the relative ease with which one can incorporate market views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Specifically, views are  University of Oxford, Oxford-Man Institute of Quantitative Finance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  †Corresponding author.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' E-mail: trent@robots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='ox.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='ac.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='uk  1  arXiv:2301.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='13594v1  [q-fin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='PM]  31 Jan 2023  given as a function of asset mean return estimates, and accompanied by an uncertainty estimate that encap-  sulates a notion of confidence about that mean.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The specification of the view uncertainty is a domain for  debate in the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In contrast, the uncertainty specification is of critical importance to the mechanics  of the Bayesian estimation framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The literature often tacitly assumes that uncertainty is to be specified  in excess of the given mean estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A prevailing method is to set the uncertainty term in proportion to a  quantity such as an estimate of the underlying return covariance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The proportionality constant can then be  tuned akin to a model hyperparameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Such ad hoc specification can be unsatisfying;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' fortunately, scientific  modelling offers an alternative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Machine learning methods are enjoying a resurgence as oracles for financial markets, particularly given the  advances underlying modern deep learning.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Indeed, such methods have utility for forecasting time-series,  and predictions are often naturally partnered with uncertainty estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Such uncertainties are typically  categorised in the literature as aleatoric or epistemic.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Aleatoric uncertainty relates to the modelled ran-  dom error of the underlying data generating process, while epistemic uncertainty encompasses much more,  including error relating to the model specification, which also subsumes uncertainties about parameter esti-  mates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' These two categories of uncertainty are recognised across multiple research domains, and the models  contained therein.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In any case, the estimation of views by statistical forecasting models, coupled with the  uncertainty estimate, allows for a more principled approach to setting view parameters when modelling with  Black-Litterman.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We describe this further in Section 3 below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This interpretation stands in stark contrast to  existing methods – with one popular technique described above – that are more ad hoc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Our approach has  the further benefits of preserving the intent of the canonical model, and has utility for automating an aspect  of the investment decision-making process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Further our extended modelling framework, we consider combining multiple views for expected returns  over the next time increment with respect to view correlation that may be non-zero.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Although we con-  sider the single-step case, we are inspired by the relationship between Black-Litterman and a state-space  modelling framework as recently described in [6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Indeed, at the core of our approach are techniques from  the information fusion literature, that allow us to combine views in a principled way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In Section 3, we  present methods for fusing views assuming both zero and non-zero correlation between them, and consider  a conservative fusion method for sets of views that may be inconsistent with one other (according to some  distance metric between distributions).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In their relative simplicity, the principles of these fusion methods  are understandable, and the resulting fused estimate are explainable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Some practitioners may find this ad-  vantageous relative to alternative black box methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In our empirical work, we find fusion-based methods  that improve on of the mean and median of our 3 view-generating models in a statistically meaningful way.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  This is interesting to the investment practitioner that cannot know ex-ante which of a set of views might  outperform;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' a fusion-based method may be selected instead.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  To show the utility of data fusion, and in connection with recent work by [4], we offer an application of the  Black-Litterman model assuming a multi-factor model for asset returns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Factor models present in finance  with various specifications;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' see [7] for a recent review.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We consider a conditional factor model, as inspired  by the Arbitrage Pricing Theory (APT) of Ross [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In Section 2, before we further develop view fusion in  Section 3, we expound on the Black-Litterman-APT as a Bayesian hierarchical model;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' a schematic for the  model is given in Figure 1 below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='3 we carefully derive the solution for the optimal portfolio  weights under an unconstrained Markowitz portfolio allocation as a further contribution to the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  With a desire to extend our empirical work, we offer a preliminary model accounting for transaction costs,  with details specified in Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='4 This model permits a reasonable proof-of-concept, that could be built  upon for industrial application or as future academic work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Notes for the data set construction are offered in Section 4.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' To the extent the raw data is available in the  2  Figure 1: LHS: Schematic of the Black-Litterman methodology as it applies to the APT model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Asset returns  are linearly projected onto factor returns, and the algorithm at the level of the factor model is such that at  each time-step views are collected, before the factor returns model is updated and predictions gleaned.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' RHS:  Hierarchical schematic suggestive of the relationship between terms in the BL-APT model, as described in  Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  public domain (via the Wharton Research Data Service), these notes could lead to a straightforward repli-  cation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In Section 5, we use the ideas and results of the preceding sections to give empirical results that  showcase view fusion whereby estimates – including measures of uncertainty – are sourced from a collec-  tion of machine learning models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We discuss the ways in which fusion-based methods lead to investment  outperformance relative to methods based on a singular view.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We also constrast our methods with the dif-  ficult benchmark of a buy-and-hold investment in the S&P 500.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We conclude and summarise avenues for  future work in Section 6.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  2  Black-Litterman  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1  A recap  Assume there exist n investable assets within a market with excess return vector r whose distribution is  modelled as multivariate normal over discrete time increments, denoted r ∼ MVN(µ, Σ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Here µ denotes  the mean vector of returns, and Σ denotes the return covariance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Then in a Markowitz Modern Portfolio  Theory framework [9], assuming a single-period investment setting, the investor portfolio weights w =  (w1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=', wn) are a solution to the mean-variance optimisation problem:  max  w∈C  E(w′r) − γ  2var(w′r).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (1)  Here C is a set of weight constraints, if any, and γ > 0 is the investor risk aversion parameter, denoting  preferences balancing return and risk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In the unconstrained case, differentiating eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (1), setting it to 0 and  3  Factor returns  qQ  sv  Collect  view  Update  F  μf  model  D  Predict  f  X  Asset returns  Induces return  distribution  estimate and  r  portfolio  allocationsolving for the optimal portfolio weights w∗ in terms of (µ, Σ) yields  w∗ = (γΣ)−1µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (2)  On analysing the second derivative one finds that this solution is indeed a maximum.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In practice, these  weights could be solved for – and a portfolio subsequently implemented – upon estimation of the return  distribution parameters, for example, upon substitution of a computed sample mean vector and sample  covariance matrix, given historical data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The Black-Litterman model [1] extends this framework to incorporate (subjective) investor beliefs about  asset returns, that are called ‘views’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A single view is assumed to be a function of real-valued vectors  of length n denoting portfolio weights p and expected asset returns µ, a real-valued scalar denoting the  portfolio value q, and a strictly positive real-valued scalar ϵ denoting uncertainty in the portfolio value, that  can be written  p′µ = q + ϵ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (3)  To be explicit, let us call a collection of k views a ‘range’, for natural numbers k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Then similar to the original  presentation of Black and Litterman, a range of views can be arranged thus:  P µ = q + ϵ,  ϵ ∼ N(0, Ω).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (4)  Here P ∈ Rk×n is a real-valued matrix of portfolio weights, where the kth row is given by p′  k as defined  above;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' q ∈ Rk is a real-valued vector collecting k portfolio values;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' and Ω ∈ Rk×k is assumed to be a  diagonal matrix of portfolio value estimate uncertainties, where we have further assumed independence  between views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Given the above formulation, a view can express both ‘absolute’ and ‘relative’ relationships between mean  asset returns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The case of an absolute (normalised) view corresponds to p taking a unit value at the ith  entry, and zero otherwise, so that the left-hand side of eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (3) equals µi.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Any other (non-trival) view we call  relative;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' a common relative view, for example, is a belief on the return spread µi − µj = q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This could be  expressed by setting alternate positive and negative unit values at the i and j index of p, and zero elsewhere.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  In the work that follows, we assume absolute views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We further assume that P is of full rank.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Given these preliminaries, the Black-Litterman model is such that the existing return distribution parameter  assumption is updated given views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We understand such updating in the context of Bayesian statistics, as  prior authors have noted [2–4, 6].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The Bayesian specification assumes a prior distribution p(θ), where θ denotes the target parameter of the  return distribution that we wish to express via a parametric probabilistic model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Most commonly, θ = µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The original authors – and many since – set the prior given an estimate of the CAPM model [5], and hence  underwriting the prior with a foundational theoretical result.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Next, the view is related to the target parameter via a likelihood function p(q|θ), such that, by the laws of  conditional probability and Bayes’ Theorem, an updated posterior distribution for the target parameter is  given by  p(θ|q) ∝ p(q|θ)p(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (5)  Finally, we can write a posterior predictive distribution for the asset returns given the views as  p(r|q) =  �  p(r|θ)p(θ|q)dθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (6)  Hence, the expectation and covariance of the random quantity r|q can be computed analytically – or other-  wise estimated if the integral is intractable – before substitution into, say, eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (2) to yield a solution to the  portfolio allocation problem.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  4  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2  Black-Litterman in the context of Factor models  In line with recent work by [4], we offer an application of the Black-Litterman model assuming a factor  model for asset returns, and we conveniently conform with some of their notation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  For context, we note that in many investment studies of equity markets the empirical estimation of the return  covariance is challenging, especially when the universe of equities under consideration is large.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The linear  factor model that we outline below, whereby k ≪ n, is relatively practical and efficient.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This has contributed  to its popularity within the literature, and bolsters the case for industrial use [10].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We consider a conditional  factor model, as inspired by the Arbitrage Pricing Theory (APT) of Ross [8].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In the single-period investment  setting, we model  r = Xf + ϵr,  ϵr ∼ N(0, D).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (7)  Here r is the n-dimensional random vector containing the cross-section of excess returns for n equities over  the next time increment [t, t+1];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' X is a non-random n×k matrix of observable factor exposures estimated  at t, for k the number of explanatory asset factors;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' D is a covariance matrix for the returns, also known at t  and assumed to be diagonal;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' and f is a k-dimensional latent factor vector that we estimate at each time step  by cross-sectional regression.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Within a Black-Litterman framework, consider that our parameter of interest  is now θ = µf, such that  f = µf + ϵf,  ϵf ∼ N(0, F ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (8)  We refer to the elements of µf as the factor risk premia.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Black-Litterman in the context of APT, henceforth labelled ‘BL-APT’, amounts to a Bayesian hierarchical  model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A schematic for the model is given in the right-hand panel of Figure 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We note that in comparison  to the Black-Litterman model applied to the return mean, an analogue to the CAPM prior does not exist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  In the work that follows, we set the prior parameters as a simple function of recent data, per the discussion  in Section 5.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' On the other hand, view estimates for the factor risk premia at time t induce return forecasts  (with uncertainties) over the next time period.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' These parameter estimates can then be utilised to estimate  portfolio weights.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  In the next section, we carefully show the derivation for the optimal portfolio weights of an unconstrained  ‘BL-APT’ as a reference contribution to the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='3  Solving for optimal weights – Hierarchical Bayesian Black-Litterman for APT  We can express our model for asset returns, factor returns and views carefully as a hierarchical Bayesian  model, with a suggestive schematic shown in Figure 1 above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We derive the optimal portfolio allocation  after finding p(r|q), as defined below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We begin by writing the joint distribution of random variables of interest as a conditional probability:  p(r, f, θ, q) = p(r, f|θ, q)p(θ, q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Substituting p(θ, q) = p(θ|q)p(q) and dividing both sides by p(q) yields  p(r, f, θ|q) = p(r, f|θ, q)p(θ|q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Integrating both sides over θ we find that  p(r, f|q) =  �  p(r, f|θ, q)  �  ��  �  =p(r,f|θ)  p(θ|q)dθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  5  Again integrating both sides, this time with respect to f, we have that  p(r|q) =  ��  p(r, f|θ)p(θ|q)dθdf.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (9)  With one more simplification, writing p(r, f|θ) = p(r|f, θ)p(f|θ) = p(r|f)p(f|θ), we find  p(r|q) =  �  p(r|f)  �  p(f|θ)p(θ|q)dθ  �  ��  �  =p(f|q)  df.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (10)  Since we assume θ = µf, there holds the well-known facts that the posterior p(θ|q) is normal and that the  posterior predictive p(f|q) is normal.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Hence it is clear that p(r|q) is also normal, with its expectation and  covariance given in closed-form by the following three-step process.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Firstly, choosing the prior p(θ) ∼ N(ξ, V ), by Bayes’ rule for linear Gaussian systems, as in [11], we have  that the posterior p(θ|q) is multivariate normal with covariance and mean  var(θ|q) = (V −1 + Ω−1)−1,  E(θ|q) = var(θ|q) · (V −1ξ + Ω−1q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Secondly, recall the convolution integral for sums of random variables: if Xi  i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='i.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='d.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  ∼ N(µi, Σi), i = 1, 2, then  f(z) :=  �  fX1(x)fX2(z − x)dx ∼ N(µ1 + µ2, Σ1 + Σ2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (11)  Writing the inner integral of eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (10) with the change of variable f �→ f − θ, we find  p(f|q) =  �  p(f − θ|θ)  �  ��  �  ∼N(0,F )  p(θ|q)dθ  so that by eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (11) we have that p(f|q) is normally distributed with expectation and covariance given by  E(f|q) = (V −1 + Ω−1)−1 · (V −1ξ + Ω−1q) = E(θ|q),  var(f|q) = (V −1 + Ω−1)−1 + F = var(θ|q) + F .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Thirdly, we solve the outer integral of eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (10) (deferring some of the details of the algebraic manipulations  to the Appendix, for brevity).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Writing  p(r|q) =  �  p(r|f)p(f|q)df,  (12)  we collect and expand the terms in the exponent up to a factor of − 1  2, complete the square in f, and integrate  what is recognisable as a Gaussian integral.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' By the recursive nature of the integrals, it is clear that we also  retrieve a Gaussian for r|q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Hence, as supported by further calculations within the Appendix below, we  have that the posterior predictive distribution p(r|q) is multivariate normal with covariance and mean  var(r|q) =  �  D−1 − D−1X  �  XT D−1X + var(f|q)−1�−1XT D−1�−1,  E(r|q) = var(r|q)D−1X  �  XT D−1X + var(f|q)−1�−1var(f|q)−1E(f|q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  By eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (2), we write the optimal weights for a single-step Black-Litterman portfolio allocation as  h∗  blb = γ−1var(r|q)−1E(r|q)  = γ−1D−1X  �  XT D−1X + var(f|q)−1�−1var(f|q)−1E(f|q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (13)  This expression differs meaningfully with other optimal weights given in the literature.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This is the case in  that we have carefully accounted for all of the specified terms within the hierarchy of the returns model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  6  2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='4  An optimal weight model under transaction costs  In this section we consider a more realistic objective function for solving for portfolio weights, in that it  incorporates transaction costs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We do this by making a minimal adjustment to the Markowitz objective of  eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (1):  max  w∈C  E(w′r) − γ  2var(w′r) − TC,  (14)  with TC denoting transaction costs measured in percentage of invested wealth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Of the many ways to account  for transaction costs, we broadly follow the single-period model recently presented in [12].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Despite the  differences in our application domains, our analysis and results contrast somewhat consistently, and certainly  interestingly, with theirs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Firstly, we choose a transaction cost model inspired by [13] so that transaction costs measured in dollars,  TCd, is given by  TCd  t = 1  2∆′  tΛt∆t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Here ∆t is the portfolio turnover vector for a time increment, defined as  ∆t := Πt(wt − Rt−1wt−1),  and the ‘market impact’ vector m is given by  mt = 1  2Λt∆t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We use the subscript t to explicitly account for time-dependence.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The real scalar Πt denotes total wealth  investable at time t.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Clearly, given the above specification dollar transaction-costs erode dollar returns  quadratically with increasing wealth.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The term Rt−1 denotes a diagonal matrix whose diagonal elements  account for the realized returns for the assets held in the portfolio at t − 1, over the time step [t − 1, t), and  adjusted for wealth delta.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We assume that the term Λt is a diagonal matrix whose elements depend on the  daily (dollar) volume traded in each underlying asset.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Given the recent estimates of [14], we assume a 10  basis point market impact when trading 1% of the daily dollar volume Lt of US equity underlyings whether  long or short, so  mt = 10bps · 1 = 1  2Λt × 1%Lt  =⇒ Λt = 1  5L−1  t .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (15)  In the work that follows, we set the values for daily dollar volumes at their 6 month rolling average.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Further,  we assume that investor wealth grows proportionally with the market;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' specifically, we make the somewhat  arbitrary assumption that at each time step the total investable capital is one-tenth of the sum of the daily  dollar volumes of the assets in our trade universe, as known at the most recent time step.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Hence eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (14) can be written, noting that TC = TCd/Π, as  max  wt∈C  E  �  w′  trt  �  − γ  2var  �  w′  trt  �  − Πt  2  �  wt − Rt−1w∗  t−1  �′Λt  �  wt − Rt−1w∗  t−1  �  (16)  and conveniently solved in closed-form for optimal weights:  w∗  t =  �  γΣt + ΠtΛt  �−1�  µt + ΠtΛtRt−1w∗  t−1  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (17)  Hence the optimal portfolio weights for the BL-APT model can be found by substituting estimates for  E(r|q) and var(r|q) into eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (17), as an alternative to eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (13), when taking transaction costs into account.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  7  3  View fusion  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1  Preliminaries  The Black-Litterman model – sans solving for the portfolio weights – can be expressed via a state-space  representation;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' this was recently presented in [6] in the context of modelling temporal dependency in asset  returns and parameter view estimates1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In a simple case, consider ranges of views generated from a source  at discrete time increments k = 0, 1, .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We can infer the underlying target mean µk in an online way, via  the linear time-varying system of equations:  µk+1 = µk + ϵµ  k ,  (18)  qk = Pkµk + ϵq  k.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (19)  Here ϵµ  k and ϵq  k model independent zero-mean white-noise processes with respective covariances Ψk and  Σk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We call equations (18) and (19) the ‘state’ and ‘measurement’ equations, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Solving the state-  space representation of Black-Litterman, assuming absolute views, we have the probability distribution for  µk|qk, analogous to eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (5) and solved equivalently to solving for p(θ|q) per Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The predictive  distribution for µk+1|qk, analogous to eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (6) can be solved equivalently to solving for p(f|q), also of  Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' On the other hand, within the Black-Litterman literature, as in our model from Section 2,  the prior is typically re-initialised to p(µ0) at each time-step, rather than dynamically updated given a  sequence of view estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In the following work, we follow this approach, and leave consideration of  prior updates based on a larger subset of recent data as future work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In any case, such state-space modelling  naturally inspires an extension of the Black-Litterman framework to handle the combination – or ‘fusion’ –  of multiple views held about a particular portfolio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2  Information fusion  To this point we have described the Black-Litterman model assuming a singular source for a range of views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Next, we consider the realistic – though in the context of Black-Litterman modelling, unexplored – case of  multiple sources generating views simultaneously for each time increment, and analyse the impact on the  predictive distribution.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We extend eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (19) thus (for brevity, keeping to the case of absolute views):  qk,s = µk,s + ϵ(q)  k,s,  (20)  where qk,s denotes the view is from source s, 1 ≤ s ≤ S, and each ϵ(q)  k,s is a zero-mean white-noise process  with covariance Σk,s.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Multiple views could realistically arise in the context of implementing a systematic  trading or asset management strategy, whereby multiple predictions across multiple (potentially, broadly  diverse) models need to be fused before capital allocation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Information fusion has been common to the state-space literature since the work of [16].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' However, fusion  is not limited to the state-space framework, and instead applies more generally to the problem of fusing  multiple estimates of an underlying random variable2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Correspondingly, data fusion can take place at the  level of the state or measurement equations, though we assume the former for our empirical work below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Typically, fusion techniques amount to solving for an optimal fused estimate (�µ, �Σ) for the true underlying  values (µ, Σ) given a collection of S underlying estimates {(�µs, �Σs) : 1 ≤ s ≤ S}, with the mean  1There exists an extensive literature on state-space modelling, with applications across many domains.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' See, for example, [15] for  an instructive review of filtering methods for mathematical finance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  2Various approaches exist in the data fusion literature for incorporating information from multiple sources;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' introductory reviews  can be found in [17, 18].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  8  Figure 2: Concentration ellipses for three example bivariate Gaussian measurements of a single state x =  (x1, x2) (light orange), and the optimal fused state estimates for the four methods outlined in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  parameter a weighted linear combination of the underlying estimates:  �µ =  �  s  Ws �µs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (21)  [We have omitted the subscript k, for ease of notation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='] ‘Optimal’ fusion is such that (i) �Σ is minimal  in some sense – typically with respect to matrix trace or determinant;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' and also that (ii) �Σ is consistent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Within the fusion literature, a consistent estimate is such that �Σ ≥ Σ, in the sense that �Σ − Σ is positive  semi-definite.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' That is, the consistent estimate subsumes a covariance no less than the covariance Σ of the  distribution of the true underlying process;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' see, for example, [19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We note that this definition is independent  of the well-known definition of a consistent estimator from the statistical literature, whereby a parameter is  called consistent if it converges in probability to the true value of the parameter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The consistency property is  crucial for many investors conscious of risk, in particular those that do not want to understate risk3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Another  benefit of consistency is that probabilistic bounds for the state of the system can be deduced, as discussed in  [21].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Given the mean and covariance of a bivariate random variable, recall the ‘concentration ellipse’ [22] defined  as the locus of points {x : (x − µ)T Σ−1(x − µ) = 1}.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' For visual intuition, we depict such ellipses,  estimated using the fusion methods described in the following subsections, in Figure 2 above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' These results  are shown for the case of three underlying data sources, assumed to each yield a noisy estimate of the same  target.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  3In the case of (multi-period) Kelly investing, to which the fusion of this paper could directly apply, investment size is inversely  proportional to variance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' But the investor faces almost sure ruin if they sufficiently over-invest (which can happen if uncertainty is  estimated to be too small) relative to the optimum strategy [20].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  9  PW  CI  2  ICI  CU  1  x2  +  0  1  1  0  1  2  3  x13.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1  Precision-weighted fusion  We first consider precision-weighted (PW) fusion for the case that the cross-covariances between sources is  known to be 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Suppose that for each s, �µs is an unbiased estimate, and each �Σs is a known error covariance  estimate that is consistent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' It follows that the fused estimate given in eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (21) is an unbiased estimate if and  only if �  s Ws = I, for weight matrices Ws, and I the identity matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' To find the weight estimates we  solve  min  W  trace(�Σ) subject to  �  s  Ws = I.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Let �Σij denote the cross-covariance estimate between the unique sources si and sj, and write  �Σ =  �  s  Ws �ΣsW T  s +  �  si̸=sj  Wsi �ΣijW T  sj.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (22)  Assuming the cross-covariances are everywhere 0, solving for the optimal weights one finds that, on weight  substitution,  �Σ = (�Σ−1  1  + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' + �Σ−1  S )−1,  (23)  �µ = �Σ(�Σ−1  1 �µ1 + .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='..' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' + �Σ−1  S �µS).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (24)  Further details of this well-known result can be found in [16, 23].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The analogous result for fusing two  sources that have known, non-zero correlation is given in [24], though for our financial modelling framework  this is less useful since the cross-correlations are not estimated.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' On the other hand, the case of unknown,  potentially non-zero cross-correlation is the domain of the Covariance Intersection method, as presented in  the following subsection.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2  Covariance Intersection  One could reasonably expect that views on the same underlying asset returns, as functions of similar or  equal underlying data, exhibit non-zero cross-correlation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' However, the cross-correlation is not necessarily  known, or easily estimable.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Such a setting is the domain of application for the Covariance Intersection (CI)  fusion method of [25].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The insight of this approach is that, given eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (22), the covariance ellipses for {�Σs}  contain �Σ in their intersection, for any values of the cross-covariance terms.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Hence the method yields  �Σ−1 =  �  s  ωs �Σ−1  s ,  (25)  �µ = �Σ  �  s  ωs �Σ−1  s �µs,  (26)  for scalars ωs ∈ [0, 1] with �  s ωs = 1, since a convex combination of covariances ensures �Σ encloses the  intersection region.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The ωs terms can be computed via a standard optimization routine subject to minimising  the trace of �Σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Further, it has been shown that the CI method applied to a pair of consistent estimates yields  a consistent estimate [19].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Finally, equations (25) and (26) as given above extend the canonical case of two  sources, as offered in [26].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  CI is a straightforward method that holds for any cross-covariance, but a cost of its flexibility is that the esti-  mate can be too conservative for many practical use cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We next consider Inverse Covariance Intersection  that attempts to retain the consistency benefit of CI, while being less conservative.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  10  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='3  Inverse Covariance Intersection  The method of inverse Covariance Intersection (ICI) is similar in approach to that of CI, but achieves a less  conservative estimate while still maintaining consistency.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The algorithm was presented recently in [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A  central insight, inspired by [28], is to first consider estimates pairwise, such that for s = 1, 2:  �µs = �Σs  �  (�Σs)−1 �µs + Γ−1γ  �  ,  (27)  �Σs =  �  (�Σs)−1 + Γ−1�−1  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (28)  This is to say, that each estimate is itself the PW fusion of a sub-estimate from the collection {(�µs, �Σs) :  1 ≤ s ≤ 2}, for sub-estimates uncorrelated between sources, and a shared set of information denoted  (γ, Γ), also uncorrelated with each sub-estimate;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' we proceed assuming such a decomposition exist.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' If the  shared information is known, then fusion can be solved optimally by subtracting the shared covariance from  the PW fusion covariance for the original pair of estimates [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' But since it is not known, the second  insight is to instead solve for, and subtract, an upper bound for the shared covariance, valid for any true  underlying shared information.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Further, regardless of the shared information, it is shown that a consistent,  tight covariance estimate – if it exists – is of the form  �Σ−1 =  2  �  i=1  �Σ−1  s  −  �  2  �  s=1  ωs �Σs  �−1  ,  (29)  for scalars ωs as in the case of CI, with the ICI covariance estimate achieving this form exactly [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' With a  modicum of algebra, it follows that the fused mean is given by  �µ =  2  �  s=1  Cs �µs,  (30)  where Cs = �Σ ·  �  �Σ−1  s  − ωs  �  2  �  s=1  ωs �Σs  �−1�  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  It is important to regonise that this formula does not generalise to more than two information sources in an  obvious way – the ICI algorithm fuses information sources pairwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' However, ICI can be applied recur-  sively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This follows from the assumption that any pairwise-fused estimate has a decomposition analogous  to equations (27) and (28) [27].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' For further results and details we also recommend [29].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='4  Covariance Union  The fusion methods outlined above assume that each source’s estimate is itself consistent with respect to  the target.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We relax this assumption by requiring that at least one of the source estimates is consistent.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A  given estimate could be inconsistent, as evidenced by, say, mean components sufficiently different between  estimates, given relatively smaller covariance estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This could be apparent, for example, when the  Mahalanobis distance between some pair of estimates exceeds a critical threshold.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Further, we may not  know precisely which of the underlying estimates is consistent, or it may be (in some sense) costly to  resolve.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The Covariance Union (CU) algorithm has been proposed as a fusion method for this setting [30].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  CU constructs a fused estimate guaranteed to be consistent, since the fused estimate is consistent with  respect to each underlying estimate:  �Σ ≥ �Σs + (�µ − �µs)(�µ − �µs)T ,  1 ≤ s ≤ S.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  11  Figure 3: Cumulative factor returns to risk premia as described in Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' replication of Figure 1 of [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  A single year is shown for ease of visualisation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The year 2011 is arbitrarily chosen.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  While the idea behind CU is relatively simple, the numerical implementation for estimating the fused esti-  mate is more challenging.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In an attempt to simplify the computation, we offer the following details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Firstly,  CU can be implemented using non-convex optimisation software such as SolvOpt [31].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We follow [32] for  implementing a SolvOpt-based solution for calculating the results of Section 5 below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Secondly, a key step  is to define the coefficient vector that we wish to solve for, x.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The first n elements of x are the elements of  �µ, and the remaining n(n+1)  2  elements of x are the elements of the upper triangle of �Σ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Then x becomes the  optimization target for SolvOpt.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We seek to minimise the determinant of �Σ subject to the constraint that  ∀s,  �Σ∗  s := �Σ − �Σs − (�µ − �µs)(�µ − �µs)T ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (31)  A particular feature of the SolvOpt software is that it requires a constraint c(x) such that, for any input,  c(x) ≤ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Since �Σ∗  s is required to be positive semi-definite, it must have non-negative eigenvalues for all  choices of s, and the constraint is satisfied for a choice of c such that  −c(x) := min{{eigenvalues(�Σ∗  s) : ∀s}} ≥ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Finally, for the interested reader, the works of [32, 33] offer further efficient approximation methods for  implementing CU, as required for particular practical use cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  4  Data  We describe the data set construction for replicating the empirical example for BL-APT of [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This con-  struction matches the original descriptions as closely as possible, and we make note of any additional re-  quired assumptions made.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' While we have attempted to carefully reproduce the database, our results need  12  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='10  market beta  size  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='08  volatility  momentum  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='06  value  cuml factor return  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='00  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='02  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='04  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='06  2011-01  2011-03  2011-05  2011-07  2011-09  2011-11  2012-01  datenot match exactly.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Not in the least, we have no guarantee that the underlying database that we call is the  same 5 years later, even if our data replication process is perfectly faithful.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A visual comparison can be  made between our factor values against the source given Figure 3 above, which demonstrates a reasonable  replication.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The data is sourced fom CRSP and IBES databases with access granted via the Wharton Research Data  Service.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The original work sourced daily US equity market data from 1992-2015;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' we extend our data set till  2022 to include the market crash of March 2020, and subsequent market rebound, for interest’s sake.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  For each day, set n = 2000 and select the top n stocks within the US market sorted by market capitalisation.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The data set is filtered for USD denominated common stock only – there are no closed end funds, REITs,  ETFs, unit trusts, depository receipts, warrants etc.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We also collected the S&P500 (excess) return time-  series, stock market capitalisations, and earnings per share, adjusted for splits.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The data set requires the creation of 5 risk factors: market beta, size, volatility, momentum and value.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The  reasonableness of our data set construction is per the output of Figure 3, which accords with expectations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We also create 70 industry factors;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' these are one-hot encoded based on the industry given by SIC.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Calculating  size is relatively straightforward in CRSP as the product of shares outstanding and the daily close price.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Value was determined by analysing IBES data, and could be merged back to the CRSP database based on  the CUSIP identifier.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We note that risk factor construction is often non-trivial.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Momentum was codable  using CRSP data and the definitions of [34];' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' we calculated the daily compounded 12 month returns sans the  most recent 1 month of data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We created the market Beta and volatility factors using the relevant CRSP data  and the details of [4].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Indeed, over a two year rolling window we estimate a collection of linear functions  by regressing each asset’s daily excess returns against the S&P500 excess returns.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The market Beta is the  regression gradient, while the volatility factor is set to be the regression mean-square error.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  The data is constructed for bi-monthly rebalancing to facilitate the experiments of the following section.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  5  Results  View models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' To proxy multiple sources of view generation, we implemented various models with utility  for forecasting financial time-series.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Indeed, machine learning models have proven useful for not only  prediction, but also for estimating prediction uncertainty.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We implement an ARIMA, boosted regression and  Gaussian Process model for generating views, and calculate model-derived uncertainty estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Relevant  details are included in the Appendix, since time-series prediction modelling is not the primary focus of this  paper.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We denote the three view models ‘ARIMA’, ‘Boost’ and ‘GP’, respectively.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We also implement the  4 fusion methods outlined in Section 3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Parameter choices.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Per Figure 1 and the outline in Section 2, the BL-APT model requires the specification  of q, F , Ω, ξ, V and D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We set q as the mean prediction estimate given by a view model, with the view  models as previously described.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The accompanying epistemic uncertainty estimate is set to Ω, and F is  set equal to the aleatoric uncertainty estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The prior hyperparameter ξ is estimated as an average of f  over a recent rolling lookback window of the most recent 20 observations.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This window size was arbitraily  decided, and is the same for all rolling windows introduced hereafter.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The total variance of each underlying  factor is calculated relative to out-of-sample data, and we yield an approximation to epistemic uncertainty  by the estimation method as described for the ARIMA model in the Appendix below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We set V as this  estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Our estimate for D is a diagonal covariance matrix equal to �σ2I, where �σ2 is the mean square  error yielded from estimating eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (7), and I is the identity matrix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Finally, we set the relative risk aversion  parameter to a constant value of 10.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Transaction costs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' An effect of accounting for transaction costs, and carefully setting the transaction cost  model parameters, is to greatly reduce portfolio turnover relative to the unconstrained Markowitz approach  13  Figure 4: View-based portfolio excess return performance net of trading costs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Benchmark SPX strategy is  gross of (negligible) transaction costs, but total returns are calculated in excess of the risk-free rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  with costs assumed nil.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Indeed, without transaction costs, it is well-known that this latter approach usually  result in unrealistic and unreasonably large leverage suggested for the optimal portfolio, and high portfolio  turnover.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Recent results of [12] show that incorporating an appropriate transaction cost model goes some  way to mitigate these limitations in empirical studies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We implement the model outlined in Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='4 above  to the same ends.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We set our portfolio rebalance period to be bi-monthly, which is sufficiently long – given  our assumed wealth process, and the potential return being signficantly larger than the cost of rebalancing –  such that the reward of updating weights is not dominated by the cost of trading.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Results – benchmark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We have tabulated performance results by year and model over a 29 year period, and  include them in the Appendix.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The method ‘S&P500 (TR)’ denotes the total return of the S&P 500 for the  year.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The annual returns may appear slightly less than commonly reported since they are net of the risk-free  rate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The S&P500 (TR) represents a useful benchmark in that it represents the market buy-and-hold strategy,  accessible to the modern day investor and with a potential for exceptionally competitive fees, especially in  the more recent years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' For comparisons sake, all results dependent on an underlying view model are reported  based on normalised underlying data, such that ex-post annualised return volatility is equal to that of the  benchmark portfolio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We make a note that, on perusing the tables, there is obvious decay in the performance  of the view-based models over the 30 year period, as evidenced, for example, by the significant decline in  Sharpe ratios over time.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Results – statistics.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We depict the Sharpe ratio statistics from the tabulated data in Figure 4 above.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The left-  most chart shows box & whisker plots for the annual Sharpe ratio for the collection of portfolio’s over the 29  year period.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Investment in the S&P500 (TR) is clearly superior to our underlying modeling approach.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' On the  other hand, there are improvements that could increase the view model performance that we deem beyond  the scope of this work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' For an easier comparison of centrality for the various method’s Sharpe distributions,  we show each portfolio’s median and mean Sharpe ratio over the 29 year period in the right-most chart.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  This visual depiction summarises how fusion and non-fusion based methods performed relative to each  other through time (and relative to the market total return portfolio).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We observe that fusion-based medians  14  median  mean  3  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='8  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='6  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2 -  2  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='0 -  ARIMA  GP  Boost  PW  CU  ICI  SPX  ARIMA  GP  Boost  PW  CU  ICI  SPX  Method  Methodare increasing through PW (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='11), CU (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='16), CI (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='38) and ICI (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='48), with the means showing a similar but  less pronounced trend.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The set of mean Sharpe ratios for the single-view based methods have a smaller range  than the medians (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='21-0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='30 versus 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='01–0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='53, respectively);' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' similarly for the fusion-based methods (0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='17–  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='31 versus 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='11–0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='48).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' When considering the mean Sharpe ratio over the full data sample, ICI outperforms  amongst the set of fusion-based methods and the single-view-based models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Similarly to the median, ICI  outperforms amongst the set of fusion-based methods and sits closely to the best of the single-view-based  models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We test for statistical significance of differences in these measures of distribution centrality per the  results in Figure 5 below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Despite the small sample sizes there is some interesting supporting evidence for  the outperformance of fusion-based methods.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We test for the difference of means between methods with a collection of pairwise 1-sided t-tests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Such  tests make a critical assumption of independence in the pairwise Sharpe ratio differences as indexed by year.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We note that despite individual time-series of model performance statistics potentially displaying serial  correlation, it seems reasonable to suggest that the the performance between models over the years does  not.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This is clearly a critical claim.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We examine the autocorrelation function for the 28 possible pairwise  comparisons and find 1 case of rejecting the null hypothesis of no autocorrelation in a Ljung-Box test at  the 10% level of significance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We further assume normality of the differences and test this with a (one-  sided) Shapiro-Wilk test for normality, also at the 10% level of significance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We find that this assumption  is rejected for 3 cases.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Finally, we assume the non-existence of outliers in the difference data, and validate  this claim on visual inspection of box and whisker plots.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  On testing for the difference of means with a paired-t test, we find, of particular interest, that ICI outperforms  the ARIMA and GP models, while CI outperforms the ARIMA only (though in this case the Shaprio-  Wilks test leads us not to rely on some of the t-test p-values).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' To support testing for significance in the  difference of means between groups, we bootstrap 2-sided bias-corrected and accelerated (BCa) bootstrap  90% confidence intervals for paired data [35].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We find evidence that ICI outperforms the ARIMA and GP  models, and again the CI outperforms the ARIMA model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We also test for the difference in medians between  groups with BCa confidence intervals, but they are broadly less conclusive.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This is potentially owing to the  small sample size.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' On the other hand, we have evidence that both ICI and CI outperforms GP on this metric.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Alternatively to testing for the difference of medians across all samples, we can test for the median of the  differences between pairwise annual Sharpes.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' To this end, we utilise the Wilcoxon signed-rank test for  paired samples [36].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In addition to assuming independence, a critical assumption is that of symmetry about  the distributions of paired differences.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Given the results of the Shapiro-Wilk tests, and visual inspection of  what appear to be reasonable QQ plots, we continue assuming symmetry is satisfied.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We perform 1-sided  tests at the 10% level of signficance and find evidence that ICI outperforms the ARIMA model for this  comparison.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  It is interesting that the CI and ICI methods achieve more compelling outperformance than the CU and PW  fusion methods, relative to the underlying view models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The assumption of PW that the underlying views  have 0 cross-covariance may be suboptimal, such that the method is yielding inconsistent estimates and in  turn impacting trading performance.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' On the other hand, perhaps CU could be utilised more sparingly and  strategically, such as when the underlying views have relatively high dispersion and so appear sufficiently  contradictory.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' An alternative fusion method such as ICI could be employed otherwise.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Corroborating our intuition about the relative strength of the S&P500 (TR) strategy relative to all others, we  see that SPX improves on all models – both single-view- and fusion-based – for almost all tests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Sufficiently  strong view models are required to compete with the market portfolio, but beyond the scope of this work.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' It  is perhaps surprising that view- and fusion-based models net of transaction costs have net positive Sharpe  ratios at all.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Indeed, we estimate global Sharpe ratios between 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='10 (PW) and 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='34 (ICI) for the entirety of  the 29 year period.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  15  Pairwise  comparison  Ljung-Box  Shapiro-Wilk  paired-t p-vals  (diff of means)  BCa CIs  (diff of means)  BCa CIs  (diff of med.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=')  Wilcoxon p-vals  (med.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' of diffs)  SPX  ICI  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='14  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='21  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='06  [ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='15, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='98 ]  [ -0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='13, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='90 ]  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='07  CI  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='14  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='45  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='05  [ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='15, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='99 ]  [ -0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='07, 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='70 ]  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='07  CU  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='12  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='75  0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='05  [ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='19, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='01 ]  [ 0.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='31, 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
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+page_content='64  Figure 5: Tabulated p-values and confidence intervals for a battery of statistical tests for comparing annual 29 years of annual Sharpe ratios pairwise  between strategies.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Yellow highlighting is applied for significance at the 10% level.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The rightmost four columns represent one-sided tests.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  16  Closing remark.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The results presented offer preliminary evidence supporting fusion-based methods within  a Black-Litterman framework subsuming a relatively complex investment strategy net of transaction costs.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Fusion-based methods result in a weighted-average performance respectful of uncertainty estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' These  methods could certainly be ex-ante preferred when all views are to be incorporated into an investment de-  cision, in the case that the best view model is unknown (and/or as in our presented work, when the method  constituting the best view model is both largely unpredictable, and changing throught time).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We have sup-  porting evidence for a rare ‘free lunch’ in financial investing by way of model fusion, essentially amounting  to a benefit we could call ‘model diversification’.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' This could be of further application in alternative trad-  ing domains, perhaps with more sophisticated underlying view models, and we hope to inspire readers to  consider their practical use.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  6  Conclusion and next steps  In this work, we further characterise view uncertainty within a Bayesian Black-Litterman framework.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In  doing so, we offer optimal portfolio weights for a case of Black-Litterman in an Arbitrage Pricing Theory  setting.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Considering the Bayesian Black-Litterman model via an equivalent state-space representation, we  are inspired by the information fusion literature for combining correlated prediction mean and uncertainty  estimates streamed from diverse sources.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Hence, we demonstrate prediction and uncertainty fusion for  multiple, simultaneous views within the Black-Litterman framework, and describe consistent uncertainty  estimation within financial investing contexts.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In our empirical work, we demonstrate the utility of our  approach for BL-APT.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Future practical work could be based on more realistic investment strategies, not the  least incorporating methods of drawdown control.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Acknowledgements  The authors would like to thank the Oxford-Man Institute of Quantitative Finance for its generous support.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Professor Stephen Roberts would like to further thank the Royal Academy of Engineering.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Trent Spears  would like to further thank Professor Nir Vulkan and Dr Jan-Peter Calliess for their helpful comments and  suggestions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  References  [1] Fischer Black and Robert B.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Litterman.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Asset Allocation: Combining Investor Views with Market Equilibrium.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
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+page_content='  [2] Jay Walters.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The black-litterman model in detail.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
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+page_content=' European Journal of Operational  Research, 258(2):564–572, 2017.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  [5] William F.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Sharpe.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Capital asset prices: A theory of market equilibrium under conditions of risk.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
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+page_content=' Blondel, P.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Prettenhofer, R.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Weiss, V.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Dubourg,  J.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
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+page_content=' Passos, D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Cournapeau, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Brucher, M.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Perrot, and E.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Duchesnay.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Scikit-learn: Machine Learning in  Python.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Journal of Machine Learning Research, 12:2825–2830, 2011.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  [39] Stephen Roberts, Michael Osborne, Mark Ebden, Steven Reece, N Gibson, and Suzanne Aigrain.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Gaussian processes for time-  series modelling.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Philosophical transactions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Series A, Mathematical, physical, and engineering sciences, 371:20110550, 02  2013.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  18  [40] Liudmila Prokhorenkova, Gleb Gusev, Aleksandr Vorobev, Anna Veronika Dorogush, and Andrey Gulin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Catboost: unbiased  boosting with categorical features.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In Advances in Neural Information Processing Systems, volume 31, 2018.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  [41] Aleksei Ustimenko, Liudmila Ostroumova Prokhorenkova, and Andrey Malinin.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Uncertainty in gradient boosting via ensem-  bles.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' 06 2020.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  [42] Salem Lahlou, Moksh Jain, Hadi Nekoei, Victor Butoi, Paul Bertin, Jarrid Rector-Brooks, Maksym Korablyov, and Yoshua  Bengio.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Deup: Direct epistemic uncertainty prediction.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' https://arxiv.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='org/abs/2102.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='08501, 2022.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' [Online;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' last  accessed 04-Dec-2022].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  19  A  Appendix  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1  Further APT calculations  This section adds further detail to the calculations of Section 2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='3.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' In determining the expectation and covariance for  r|q in the case of unknown mean but known covariance, given eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (12) we collect and expand the terms in the exponent  up to a factor of − 1  2, complete the square in f, and integrate what is recognisable as a Gaussian integral:  (r − Xf)T D−1(r − Xf) + (f − µ)T Σ−1(f − µ) = rT D−1r − 2f T XT D−1r  + (Xf)T D−1Xf + f T Σ−1f − 2f T Σ−1µ + µT Σ−1µ  = rT D−1r + f T Hf − 2ηf + µT Σ−1µ  where µ and Σ denote the mean and covariance for f|q, H := XT D−1X + Σ−1 and η := XT D−1r + Σ−1µ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Completing the square,  f T Hf − 2f T η = (f − ν)T H(f − ν) − νT Hν,  ν = H−1η,  whereby  �  exp  �  − 1  2(f − ν)T H(f − ν)  �  df =  �  (2π)k  |H| .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Therefore  p(r|q) ∝ exp  �  − 1  2  �  rT D−1r + µT Σ−1µ − νT Hν  ��  = exp  �  − 1  2  �  rT D−1r + µT Σ−1µ − ηT H−1η  ��  ,  (32)  and we retrieve the exponent of the Gaussian for r|q.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Inspired by [4], we next make use of the following Lemma:  Lemma 1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' If a multivariate normal random variable θ has density p(θ) and −2 log p(θ) = θ′Hθ − 2ν′θ +  (terms without θ) then var(θ) = H−1 and Eθ = H−1ν.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Collecting quadratic terms in r from the exponent of eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (32):  −ηT H−1η + rT D−1r = −[XT D−1r + Σ−1µ]T H−1[XT D−1r + Σ−1µ] + rT D−1r  = −rT D−1XH−1XT D−1r + rT D−1r + lower-order terms in r  (33)  = rT [−D−1XH−1XT D−1 + D−1]r + lower-order terms in r  Making use of the lemma, we have that the posterior predictive distribution p(r|q) is multivariate normal with covari-  ance  var(r|q) = [−D−1XH−1XT D−1 + D−1]−1,  = [D−1 − D−1X[XT D−1X + [(V −1 + Ω−1)−1 + F ]−1]−1XT D−1]−1.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Futher, we collect the linear terms in r from eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (33):  −rT D−1XT H−1Σ−1µ − µT Σ−1H−1XT D−1r = −2µT Σ−1H−1XT D−1r,  so that again by the lemma  E(r|q) = var(r|q)D−1XH−1Σ−1µ  = var(r|q)D−1X[XT D−1X + [(V −1 + Ω−1)−1 + F ]−1]−1  [(V −1 + Ω−1)−1 + F ]−1(V −1 + Ω−1)−1(V −1ξ + Ω−1q).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  20  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2  View fusion under model-based forecasts  Suppose we model y = f(x) + ϵ for some function f parameterised by θ, with ϵ ∼ N(0, σ2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Then we can write  y|x, θ ∼ N(f(x), σ2).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Assuming θ has prior distribution p(θ), then for a collection of data D we can update the prior  via the likelihood analogous to eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (5) above: p(θ|D) ∝ p(D|θ)p(θ).' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Then for a new data point x∗, the predictive  distribution for the corresponding y∗ can be written  p(y∗|x∗, D) =  �  p(y∗|x∗, θ)p(θ|D)dθ.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Further, the variance of the prediction, var(y∗|x∗, D), can be decomposed making use of the law of total variance, that  is:  var(y∗|x∗, D) = varθ|D  �  E(y∗|x∗, θ)  �  + Eθ|D  �  var(y∗|x∗, θ)  �  .' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  (34)  Here the subscript on the outer variance and expectation terms on the right-hand side denotes that the integral is  calculated with respect to the conditional density for θ|D.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The first term on the right-hand side we call the epistemic  uncertainty, sometimes described as a ‘model’ uncertainty associated with estimating the model parameters, and that  is reducible with increasing data.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The second term we call the aleatoric uncertainty;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' this models the underlying  stochasticity of the data distribution, and is irreducible.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  Estimation of predictive distributions or the components of model uncertainty is not always tractable;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' consequently,  various approximation methods exists for estimating these quantities.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' A review is beyond the scope of this paper;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' we  instead refer interested readers to the recent work of [37] for further details.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='2.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='1  Brief overview of view models  To yield the results of Section 5 above we first implement three diverse view models.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' For completeness, we provide  the implementation details below.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We implement a Gaussian Process model using scikit-learn in Python [38].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The kernel function is given by the sum  of a radial basis function and a white-noise kernel;' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' see, for example, [39] for context on Gaussian Processes for time-  series modelling.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We re-fit the model on a bi-monthly basis on a rolling data window of 1 year.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The predict method  is used to generate prediction estimates and an accompanying (total) uncertainty estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The uncertainty can be  decomposed into epistemic and aleatoric components by setting the latter as the noise-level parameter estimated for  the white-noise kernel.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' By eq.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' (34) above, the epistemic uncertainty is then the difference between the total uncertainty  and the aleatoric uncertainty estimates.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We implement a boosted regression model making use of CatBoost [40].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We re-fit the model on a bi-monthly basis  on a rolling data window of 2 years.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' The model yields an aleatoric uncertainty estimate owing to modelling this  uncertainty directly via the loss function.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' An estimate for epistemic uncertainty is approximated by the variance of the  underlying ensemble of predictions.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Further details of this method can be found in [41].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  We estimate an ARIMA model for view generation as a well-known baseline model.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Further, this model naturally  yields an aleatoric uncertainty estimate.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' To approximate epistemic uncertainty for this model, we are inspired by  Algorithm 3 of [42].' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We note that our method is somewhat ad hoc, and has subtle differences: we estimate prediction  error variance on a recent out-of-sample lookback window of size 6 months, estimating epistemic uncertainty as the  difference between this term and today’s aleatoric uncertainty estimate, to a minimum of 1e-8.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' We re-fit the model on  a bi-monthly basis on a rolling data window of 1 year.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  21  A.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='3  Performance results by year  Performance metrics for market total return (in excess of the risk-free rate), against a collection of Black-Litterman  models with varying underlying prediction methods to generate and/or fuse views.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content=' Methods sans the index allocation  are normalised by return volatility to equal the ex-post annual return volatility of the market index.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
+page_content='  1993  1994  Portfolio method  Cuml Ret  Ret Vol  Sharpe  IR  Sortino  Max DD  Cuml Ret  Ret Vol  Sharpe  IR  Sortino  Max DD  S&P 500 (TR)  7.' metadata={'source': '/home/zjlab/wf/langchain-ChatGLM/knowledge_base/z9FRT4oBgHgl3EQfkDeO/content/2301.13594v1.pdf'}
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